JP2008227764A - Mixer system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To maintain corresponding parameters among respective digital mixers at the same value easily, even when the correspondence of a mixing bus with output ch (channel) is variable among a plurality of digital mixers. <P>SOLUTION: In each digital mixer composing a mixer system, a system is set to an arbitrary mixing bus in mixing buses owned by itself, and acoustic signals mixed by the mixing bus in the same system in respective digital mixers are mixed further for supplying to the output ch. The presence or absence of a link can be set for each system. For each system, where the presence of a link is selected, the parameter prescribing signal processing content in the output channel is mutually maintained at the same value (S103) within the range of the output channel, to which the acoustic signals mixed in the same system are supplied in the output channels that the respective digital mixers have (S100, S101). <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a mixer system including a plurality of mixing buses, and a plurality of digital mixers each configured to process and output an acoustic signal mixed in each mixing bus by an output channel corresponding to the mixing bus.

Conventionally, as a digital mixer capable of sharing a mixing bus by cascading with other digital mixers, for example, those described in Non-Patent Document 1 and Patent Document 1 are known.
These digital mixers have a function of processing and outputting an acoustic signal mixed by a mixing bus for each mixer by an output channel (ch) corresponding to the mixing bus, and at the same time, an acoustic signal mixed by the mixing bus. The digital mixer on the downstream side of the cascade also has a function of being input to a bus in accordance with a predetermined correspondence relationship and used for mixing in the mixing bus.

  With these functions, the downstream digital mixer can mix the acoustic signal supplied from its own input channel to the mixing bus and the acoustic signal supplied from the upstream digital mixer to the mixing bus. Substantially, in addition to the acoustic signal input from the input channel included in itself, a signal input from the input channel included in the digital mixer connected to the upstream side can be output as a mixed acoustic signal.

  Further, in Non-Patent Document 1, two digital mixers are connected so as to be able to transmit and receive acoustic signals bidirectionally using a cascade connection terminal, so that either of the two digital mixers can be connected. A configuration is also described in which an acoustic signal obtained by mixing all signals input from input channels of two digital mixers can be output. In such a configuration, each output channel outputs the same output as when mixing is performed as one common mixing bus by connecting the corresponding mixing buses between the two digital mixers. Will be.

Non-Patent Document 1 and Patent Document 1 link parameters such as scene store / recall, DCA group on / off and level, and mute on / off of mute groups between cascaded digital mixers. A function is also described in which when the value of the parameter is changed by one digital mixer, the corresponding change is made by another digital mixer.
“PM5D / PM5D-RH Instruction Manual”, Yamaha Corporation, 2004, p. 139-142, 196-201 JP 2005-274822 A

By the way, in the digital mixer described in Non-Patent Document 1 and Patent Document 1 described above, when linking parameters, the connection relationship between mixing buses between cascaded mixers was not particularly conscious. .
However, if the connection relationship between the mixing buses, that is, the mixing bus of the digital mixer to which the audio signal mixed by each mixing bus in a certain digital mixer is input, is variable, certain parameters Does not simply determine who the value should be linked to. For this reason, when the connection relationship between the mixing buses is variable, there is a problem in that parameter linking cannot be performed properly.

  For example, it is assumed that the same ID (for example, 1 to 32) is assigned to a mixing bus and an output channel for outputting a signal mixed by the mixing bus. In this case, in one digital mixer, the mixing bus with ID = 1 corresponds to the output channel with ID = 1. In addition, between individual digital mixers of the same model and different, if considered simply, mixing buses with the same ID and output channels are considered to have a correspondence relationship. Therefore, when linking parameters between a plurality of digital mixers, it can be considered that the parameter values of mixing buses and output channels with the same ID should be aligned.

  On the other hand, the acoustic signal mixed with the mixing bus of ID = 1 of the digital mixer A and the acoustic signal mixed with the mixing bus of ID = 2 of the digital mixer B are further mixed and output using the cascade connection. In such a case, even if the IDs are different, it is considered preferable to handle these mixing buses as having a correspondence relationship. When the parameters of the output channels are linked, the parameter values are set for the output channel of ID = 1 of the digital mixer A that outputs the signals of these mixing buses and the output channel of ID = 2 of the digital mixer B. It may be preferable to link.

However, a technique for appropriately linking parameters in consideration of such circumstances has not been known.
Therefore, in the latter case, when it is desired to match the parameter values between the signal processing elements having different IDs, there is a problem that the setting operation is individually performed for each digital mixer, and the operation is troublesome.

  The present invention solves such a problem, and in a mixer system configured by cascading a plurality of digital mixers, each of the plurality of digital mixers, even when the correspondence between the mixing bus and the output channel is variable, It is an object of the present invention to make it possible to easily maintain corresponding parameters between digital mixers at the same value.

  In order to achieve the above object, the present invention includes a plurality of digital mixers that include a plurality of mixing buses, and that process and output the acoustic signals mixed by the mixing buses by output channels corresponding to the mixing buses. In the mixer system configured by cascade connection, system setting means for setting the system so that the mixing bus and the system have a one-to-one correspondence with any one of the mixing buses included in each digital mixer. A cascade that further mixes the acoustic signal mixed in each of the mixing buses for which the system is set by the system setting means and the signal mixed in the mixing bus for which the same system is set in another cascaded digital mixer Mixing means and cascade mixing means A cascading output means for supplying an acoustic signal mixed for each system to a mixing bus in which the system is set and the corresponding output channel is provided, and a link setting means for setting the link presence / absence for each system in the mixer system For each system that is set to have a link by the link setting means, among the output channels of each digital mixer, the range of output channels to which the acoustic signal mixed in the same system is supplied, Parameter link means is provided for maintaining parameters that define signal processing contents at the same value.

  Further, another mixer system of the present invention includes a plurality of mixing buses, and a plurality of cascaded digital mixers that process and output the sound signals mixed in the mixing buses by output channels corresponding to the mixing buses, respectively. In the mixer system configured to be connected, each digital mixer is associated with a plurality of mixing buses and a plurality of cascade-connected systems in a one-to-one correspondence with each digital mixer, and the mixing bus is associated with the system Each of the audio signals mixed with each other and a signal mixed with a mixing bus associated with the same system in another cascaded digital mixer, and a cascade mix means for further mixing each system by the cascade mix means Acoustic signal mixed in Are provided with a mixing output associated with the system and a cascade output means for supplying to the corresponding output channel, and the mixer system is provided with a link setting means for setting the presence or absence of a link for each system, and the link setting means. A parameter that defines the signal processing content in the output channel within the range of the output channel to which the sound signal mixed in the same system is supplied among the output channels of each digital mixer for each system that is set to have link Are provided with parameter link means for maintaining the same values.

In these mixer systems, the link can be set for a plurality of systems in a lump, and an acoustic signal mixed in any of a plurality of systems for which the collective link is set is supplied to the parameter link means. It is preferable to provide means for keeping the values of the parameters defining the signal processing contents in the output channel at the same value within the range of the output channel.
Further, in each of the digital mixers, for each mixing bus, it is possible to set whether or not the acoustic signal mixed in the mixing bus is to be used for mixing by the cascade mixing means, and not to be used for mixing by the cascade mixing means. It is preferable not to supply the acoustic signal mixed by the cascade mixing means to the output channel corresponding to the mixing bus that has been set.

  According to the mixer system of the present invention as described above, in a mixer system configured by cascading a plurality of digital mixers, even when the correspondence between the mixing bus and the output channel is variable between the plurality of digital mixers, It is possible to easily keep the corresponding parameter between the digital mixers at the same value.

Hereinafter, the best mode for carrying out the present invention will be specifically described with reference to the drawings.
First, the configuration of a mixer system including a digital mixer according to an embodiment of the present invention will be described.
FIG. 1 is a block diagram showing the configuration of the mixer system.

  As shown in FIG. 1, the mixer system 1 is configured by connecting three digital mixers. One of them is a digital mixer 10 having an operation panel 100, and the other two are digital mixers 30 having no operation panel. Each of these digital mixers 10 and 30 has a signal processing function sufficient to operate independently as a digital mixer. However, by connecting them together to form the mixer system 1, the digital mixers 10 and 30 are operated in cooperation with each other. In particular, it is possible to perform signal processing on a larger scale than in the case of a single unit.

Here, the configuration of the digital mixer 10 will be described first.
As shown in FIG. 1, the digital mixer 10 includes a CPU 11, a flash memory 12, a RAM 13, an external device input / output unit (I / O) 14, a waveform I / O 15, a signal processing unit (DSP) 16, a cascade I / O 17, An operation panel 100 is provided, and these are connected by a system bus 18. And it has the function to perform various signal processing with respect to the acoustic signal input from a plurality of input ports by a signal processing element including a plurality of input channels (ch), and to output.

The CPU 11 is a control unit that performs overall control of the operation of the digital mixer 10, and by executing a required control program stored in the flash memory 12, the external device I / O 14, the waveform I / O 15 and the cascade I Processing such as communication control at / O17, operation detection and display control at the operation panel 100, and setting / changing of parameter values used for signal processing at the DSP 16 are performed.
The flash memory 12 is a rewritable nonvolatile storage unit that stores a control program executed by the CPU 11.
The RAM 13 is a storage means for storing data to be temporarily stored and used as a work memory for the CPU 11.

The external device I / O 14 is an interface for connecting various external devices to perform input / output. For example, an interface for connecting an external display, a mouse, a keyboard for inputting characters, an operation panel, and the like is prepared. . Further, even if the display device and the operation element of the main body are configured to be very simple, it is conceivable that parameter change / setting and operation instruction can be performed by utilizing these external devices.
Further, as an interface for communicating with a control device such as a personal computer (PC), a USB (Universal Serial Bus) type interface, an interface for performing communication by Ethernet (registered trademark), or the like may be provided.

  The waveform I / O 15 is an interface for receiving an input of an acoustic signal to be processed by the DSP 16 and outputting the processed acoustic signal. The waveform I / O 15 is appropriately combined with an analog input terminal having an A / D conversion circuit, an analog output terminal having a D / A conversion circuit, a digital input terminal for digital input / output, and a digital output terminal. There are several. The number of terminals can be increased by an expansion board. Although not shown, the waveform I / O 15 is also provided with an operator monitor output terminal used by an operator of the digital mixer 10 to monitor a signal being processed by the DSP 16.

  The DSP 16 includes a signal processing circuit, performs various signal processing such as mixing and equalizing on the acoustic signal input from the waveform I / O 15 according to the values of various parameters stored in the current memory, and generates the waveform I / O 15. It is a signal processing means to output. It is conceivable to prepare a storage area of the current memory in a memory provided in the RAM 13 or the DSP 16 itself. Specific contents of the signal processing will be described in detail later.

The cascade I / O 17 is an interface for transmitting and receiving acoustic signals and control signals to and from other mixer engines when using a plurality of digital mixers in cascade connection, and is a cascade connection means.
The cascade I / O 17 is provided with a terminal for connecting to an upstream digital mixer and a terminal for connecting to a downstream digital mixer. When a plurality of digital mixers are cascade-connected, the connection is as follows. This is a linear connection with directionality. And between the directly connected apparatuses, bidirectional transmission / reception of a plurality of channels (here, 32 channels) of acoustic signals and control signals such as commands and responses can be performed. When these signals are transmitted to devices that are not directly connected, they cannot be transmitted directly, so that the devices connected between them are relayed in order.

  The operation panel 100 includes a display device 101, an electric fader 102, and an operation element 103. The operation panel 100 receives instructions from a user regarding parameter settings, mode changes, and the like, and the operation status of each digital mixer constituting the mixer system 1 It is a user interface for displaying a setting content or a GUI (Graphical User Interface) for receiving an operation.

  Among these, the display device 101 can be configured by, for example, a liquid crystal display (LCD), a light emitting diode (LED), or the like. It is also possible to arrange the LED on the back side of the operation element or to laminate a touch panel on the LCD so that the display unit 101 and the operation element 103 are combined.

The electric fader 102 is a slider operator provided with a driving means for moving the position of the knob, and can move the knob to an arbitrary position within the operable range under the control of the CPU 11 without any user operation. it can.
The operation element 103 is an operation element other than the electric fader 102 for receiving a user's operation, and can be constituted by various keys, buttons, dials, sliders, and the like. Further, a touch panel may be stacked on the LCD constituting the display device 101.
The above is the configuration of the digital mixer 10.

  On the other hand, the digital mixer 30 is not provided with the operation panel 100, but instead is provided with an operator 31 and a display 32 having a simple configuration for accepting power ON / OFF and very basic operations. This is different from the digital mixer 10. Along with this, the housing size and the arrangement of terminals and the like are also different from those of the digital mixer 10, but other signal processing functions provided in the DSP 16, the number of terminals provided in various I / Os, the processing capacity of the CPU 11, etc. The same as the digital mixer 10.

  That is, in the mixer system 1, the digital mixer 30 is used by cascading the digital mixers 10, but the digital mixer 30 is one independent mixer, and accepts a user's operation independently and performs signal processing accordingly. Can be executed. For the operation, another device may be connected to the external device I / O 14 and remotely controlled from the device. For example, a PC is connected to the external device I / O 14 and the digital mixer 30 is operated by remote control from the PC, or the external device I / O 14 is equipped with a display panel and a switch for scene recall, several channels It is conceivable to connect various operation panels according to the purpose such as a fader panel having a minute volume control fader and use the operation panel for the operation of the digital mixer 30.

Therefore, when the contents of the signal processing are described, it is not necessary to distinguish between the digital mixer 10 and the digital mixer 30, so in the following description, each digital mixer is basically shown in parentheses in FIG. The codes 1 to # 3 are used.
In the mixer system 1, all the parameter values used for signal processing by the three digital mixers can be set by operating the operation panel 100 of the digital mixer # 1. For this reason, the other two digital mixers # 2 and # 3 do not require a large number of operators and indicators for performing detailed operations, and therefore, only the extremely simple operators 31 and indicators 32 are provided. The size, weight, and cost can be reduced. Note that the configuration of signal processing in the DSP 16 is the same for all digital mixers, the control program for the digital mixer 10 and the digital mixer 30 is made common and simplified, and the digital mixer to be controlled or edited is switched. Although it is preferable in terms of continuity of operation at the time, it is not limited to this.

Next, FIG. 2 shows a schematic configuration of signal processing executed by the mixer system 1 shown in FIG.
The signal processing shown in FIG. 2 is basically realized by the DSP 16, and the part related to data input / output is realized by the waveform I / O 15 or the cascade I / O 17. An arrow extending from the operation panel 100 indicates that all parameter values used for signal processing in the three digital mixers can be controlled from the operation panel provided in the digital mixer # 1.

  As shown in FIG. 2, each digital mixer includes an input port 41, an input patch 42, an input channel 43, a mixing bus 44, a variable delay 45, a cascade ON switch 46, cascade buses 51 and 52, an adder 53, a folding switch 54, A selector 61, a variable delay 62, an output channel 63, an output patch 64, and an output port 65 are provided.

  Among these, the input port 41 is a port that is provided corresponding to the acoustic signal input terminal in the waveform I / O 15 and receives an acoustic signal supplied from a cable connected to the terminal. Although there are an analog input port that receives an analog signal and a digital input port that receives a digital signal, the difference is not important here, and is therefore collectively shown as an input port 41.

The input patch 42 is a function for supplying the acoustic signal received at the input port 41 to the input channel 43 used for processing the acoustic signal in accordance with the correspondence specified by the input patch data, and performing the signal processing at the input channel 43. Have
The input channel 43 is provided with 48 channels, and the signal input from the port patched by the input patch 42 is subjected to signal processing by signal processing elements such as a limiter, a compressor, an equalizer, a fader, and pan, and then 24 mixing buses. 44 has a function of sending the processed signal after adjusting the send level. In each input channel 43, output ON / OFF for each mixing bus 44 can be set.

Each mixing bus 44 has a function of mixing and outputting acoustic signals input from the input channels 43.
The variable delay 45 has a function of delaying the output acoustic signal from the mixing bus 44 for a predetermined time described later.
The cascade ON switch 46 is a switch for setting ON / OFF of the output from the corresponding mixing bus 44 to the cascade bus 51, and can be switched ON / OFF for each mixing bus. If this is ON, the acoustic signal output from the mixing bus 44 is added to the acoustic signal supplied from the digital mixer on the upstream side (upper side in the drawing) to the cascade bus 51 by the adder 53.

The cascade bus 51 performs addition processing in the adder 53 on the acoustic signal supplied from the upstream digital mixer connected via the cascade I / O 17 and is also connected via the cascade I / O 17. This is a bus for transmitting to the downstream digital mixer. The cascade buses 51 and 52 are provided in the same number of 24 systems as the mixing bus 44 and are supplied with acoustic signals from the cascade bus 51 of the same system of the upstream digital mixer. The number of cascade buses 51 to which the acoustic signal is added is determined according to the settings made by the user, as will be described later. In the most upstream mixer engine, a silence signal is input to the cascade bus 51 as a signal from the upstream side.
These cascade bus 51 and adder 53 are cascade mix means.

On the other hand, the cascade bus 52 is a bus for transmitting an acoustic signal supplied from the downstream digital mixer to the upstream digital mixer in the opposite direction to the cascade bus 51. This bus does not particularly process signals. Also in this case, in each digital mixer, the cascade bus 52 is supplied with an acoustic signal from the cascade bus 52 of the same system on the downstream side.
This cascade bus 52 is a cascade output means.

  The turn-back switch 54 is a switch for supplying the acoustic signal being processed by the cascade bus 51 to the cascade bus 52 of the same system. This switch is turned on only in the most downstream digital mixer (here, digital mixer # 1) in cascade connection. In the most downstream digital mixer, there is no digital mixer that supplies an acoustic signal to the cascade bus 52, and therefore the acoustic signal is supplied to the cascade bus 52 only from the cascade bus 51. Accordingly, in the cascade bus 52, the acoustic signals obtained by sequentially adding the acoustic signals output from the mixing bus 44 from the most upstream digital mixer (here, digital mixer # 3) to the most downstream digital mixer are added by the adder 53. A signal is supplied, and this acoustic signal is returned to the most upstream digital mixer.

The acoustic signal passing through the cascade bus 52 is supplied to the selector 61.
The selector 61 is provided in 24 units corresponding to each mixing bus 44, and an acoustic signal output from the corresponding mixing bus 44 and delayed only by the variable delay 45 is also supplied thereto. Note that which selector 61 is supplied with an acoustic signal passing through the cascade bus 52 of each system is added by a signal output from a certain mixing bus 44 according to a reverse correspondence to the addition to the cascade bus 51. It is determined that the existing acoustic signal is input to the selector 61 corresponding to the mixing bus 44. For example, if the output of the first mixing bus 44 is added to the cascade bus 51 of the third system, the acoustic signal of the cascade bus 52 of the third system is assigned to the first corresponding to the first mixing bus 44. To the selector 61.

  The selector 61 works in conjunction with the cascade ON switch 46, and selects the signal input from the cascade bus 52 if it is ON, and selects the signal input from the mixing bus 44 via the variable delay 45 if it is OFF. The former selection is performed when the function of mixing with another digital mixer using the cascade buses 51 and 52 (referred to as “cascade link”) is effective for the corresponding mixing bus 44. Yes, the signal that has been mixed is selected. The latter selection is performed when the cascade link function is invalid, and the signal that is output from the mixing bus 44 is selected.

In any case, the acoustic signal selected by the selector 61 is delayed by the variable delay 62 and then supplied to the corresponding output ch 63. The delay in the variable delay 62 is for adjusting the transmission delay generated in the cascade link, as will be described later, together with the delay in the variable delay 45.
The output channels 63 are provided in 24 channels corresponding to the 24 mixing buses 44, and each output channel 63 outputs a signal to a sound signal input from the corresponding bus by a signal processing element such as a limiter, a compressor, an equalizer, or a fader. It has a function of performing processing and outputting the processed acoustic signal to the output patch 64.

The output patch 64 has a function of supplying the acoustic signal output from each output channel 63 to the output port used for outputting the acoustic signal according to the correspondence specified by the output patch data.
The output port 65 is provided corresponding to the waveform I / O 15 and the acoustic signal output terminal, and the waveform I / O 15 is a cable in which the acoustic signal supplied to the output port 65 is connected to the corresponding acoustic signal output terminal. Output for. The output acoustic signal is used for a purpose according to the device of the connection partner, such as sound generation if the connection partner on the opposite side of the cable is a speaker, and sound recording if the recorder is a recorder.

The above is the schematic configuration of the signal processing executed by the mixer system 1. However, here, in order to simplify the description, a difference in function between a plurality of buses and channels is not a problem. However, buses and channels having different functions may be provided. For example, an ST input channel or a channel for inputting an acoustic signal processed by a built-in effector (not shown) may be provided as the input channel 43, or an ST bus, AUX bus, CUE bus, or the like may be provided as the mixing bus 44. It is done. In this case, the variable delays 45 and 62, the selector 61, and the output channel 63 are also provided corresponding to each mixing bus. Cascade buses 51 and 52 are provided in the same number as the mixing bus for each type of mixing bus, and corresponding types of cascade buses are assigned to the mixing bus in a one-to-one correspondence.
Further, the functions of the respective units shown in FIG. 2 may be realized by software or hardware.

Next, functions of the variable delays 45 and 62 will be described with reference to FIGS.
FIG. 3 is a diagram illustrating a flow of an acoustic signal supplied to the cascade bus, and FIG. 4 is a diagram illustrating functions realized by the cascade link.
With the function of each unit shown in FIG. 2, in the mixer system 1, as shown in FIG. 3, the acoustic signal mixed by the mixing bus 44 is supplied to the cascade bus 51 and supplied in order from upstream to downstream of the cascade connection. The sound signals to be added can be added by the cascade bus 51. Then, the added acoustic signal can be supplied from the cascade bus 52 to the output channel 63 of each digital mixer.

  As a result, as shown in FIG. 4, all the mixing buses are connected to each of the digital mixers # 1 to # 3 constituting the mixer system 1, and the acoustic signal processed by the input channel 43 of each mixer is shared by the common mixing bus. It is possible to obtain an output as if it was input to 44 'and mixed.

  Note that, as shown in FIG. 3, when the acoustic signals being processed by the cascade buses 51 and 52 are transmitted between adjacent digital mixers, a certain transmission delay occurs. Therefore, in each device, if the acoustic signal mixed by the mixing bus 44 is simply supplied to the cascade bus 51, signals having different timings are added. Therefore, the timing at the time of addition can be adjusted by adding the same delay as the transmission delay generated from the most upstream digital mixer to the own device by the variable delay 45 before the supply to the cascade bus 51.

  In addition, if an acoustic signal supplied from the cascade bus 52 is simply output at the time of output, an acoustic signal whose timing is shifted by the transmission delay is output. Therefore, by adding a delay equal to the transmission delay generated from the own device to the most upstream digital mixer to the acoustic signal supplied from the cascade bus 52 by the variable delay 62, the acoustic signal output by each digital mixer is output. The timing can be adjusted.

  In addition, as indicated by the broken line, an acoustic signal mixed by any bus in the mixing bus 44 can be output to the output channel 63 without passing through the cascade bus. In this case, since there is no transmission delay in the output acoustic signal, the timing may be different from that of the cascaded acoustic signal. Therefore, although not shown in FIG. 2, a variable delay for adjusting this timing shift may be inserted between the variable delay 45 and the selector 61.

Next, FIG. 5 shows a configuration of the operation panel 100 included in the digital mixer 10.
As shown in FIG. 5, the operation panel 100 is provided with various indicators and operators.
Among these, the input channel strip unit 110 is a part provided with a channel strip for editing parameter values used for signal processing in the input channel 43.
The channel strip is a group of operators that collects operators for editing parameter values related to one channel. However, it is not necessary to be able to edit all the parameters of one channel only by the channel strip operator, and an assignable operator that can assign the parameter item to be edited may be included.

The input channel strip unit 110 is provided with 16 channel strips as described above, and by assigning an input channel to each channel strip, the input channel strip unit 110 can function as an operator for editing the parameters of the allocated input channel. .
Also, a plurality of correspondences between the contents of this assignment, that is, the ch strip and the input channel, are prepared in advance as input channel layers. Then, a layer selection switch 111 corresponding to each input channel layer is provided, and by operating the layer selection switch 111, an input channel layer corresponding to the operated switch is selected, and along the contents of the input channel layer, An input channel can be assigned to each channel strip of the input channel strip unit 110.

  Here, for each of the 16 channel strips, an input channel layer to which the 1st to 16th input channels are allocated, an input channel layer to which the 17th to 32nd input channels are allocated, and an input channel to which the 33rd to 48th input channels are allocated. Three input channel layers with layers are prepared. Then, by appropriately selecting these, the value of the parameter relating to the 48 ch input ch 43 can be edited with 16 ch strips.

  Next, the output channel strip unit 120 is a part where channel strips for editing the values of parameters used for signal processing in the output channel 63 are provided for 8 channels. An output channel layer to which the 1st to 8th output channels are allocated, an output channel layer to which the 9th to 16th output channels are allocated, and an output channel to which the 17th to 24th output channels are allocated to the eight channel strips. Three layers are prepared, and an output channel layer can be selected by a layer selection switch 121 corresponding to these layers. Therefore, the value of the parameter relating to the 24 ch output ch 63 can be edited by the 8 ch strip.

The contents of the layers related to the input channel strip unit 110 and the output channel strip unit 120 are fixed, and are stored in the flash memory 12 of the digital mixer 10.
On the other hand, the multi-use ch strip unit 130 is also a portion provided with ch strips for 8 ch, but the contents of the multi-use layer that determines the ch assigned to the ch strip can be freely edited by the user.

FIG. 6 shows the configuration of the ch strip in the multipurpose ch strip unit 130.
As shown in this figure, the channel strip 160 includes a display 161, a rotary encoder 162, a selection switch 163, an on switch 164, a fader operation element 165, and a cue switch 166.
Among these, the display 161 is a small liquid crystal panel having a backlight of a plurality of colors, and is a display means for displaying a character string indicating the channel assigned to the corresponding channel strip. The character string used for this display is set by the user as a part of the information of the versatile layer as will be described later.

  Further, in the display device 161, which digital mixer channel is assigned to the ch strip 160 according to the color of the backlight to be turned on, that is, which digital mixer parameter is edited using the operation unit of the ch strip 160. Can be displayed. For example, it is conceivable that the backlight is lit in blue when digital mixer # 1 is assigned, green in # 2, red in # 3, and white when not a specific mixer.

  The rotary encoder 162 and the fader operator 165 are assignable operators. For example, it is conceivable to assign pan to the rotary encoder 162 and fader to the fader operator 165. These assignments can be made by the operators of the SW groups 145 and 148 shown in FIG. A fader operator 165 corresponds to the electric fader 102 in FIG.

The selection switch 163 is an operation element for selecting a corresponding channel and making it an operation target by an operation element of the selected channel operation unit 141 or displaying a screen for displaying information on the channel on the display panel 143.
The on switch 164 is an operator for setting output on / off in the corresponding channel.

The cue switch 166 is an operator for setting on / off of the output of the acoustic signal processed by the corresponding channel to the CUE bus for generating a monitor signal.
It should be noted that the configuration of ch strips provided in other ch strip portions such as the input ch strip portion 110 and the output ch strip portion 120 does not necessarily match this. That is, the number and type of operators provided on the ch strip may be different for each ch strip portion.

  Returning to the description of FIG. 5, the layer selection switch 131 is a switch for selecting a multi-use layer used for channel assignment in the multi-use ch strip unit 130. Here, a total of seven switches are provided: a switch for selecting six types of versatile layers that can be defined by the user and a switch for selecting a fixed DCA layer.

  Note that the channels that can be assigned to the multi-use channel strip unit 130 by the multi-use layer and the information included in the multi-use layer are wider than those in the case of the input channel layer and the output channel layer. Along with this, the processing performed by the digital mixer 10 in accordance with the operation of the layer selection switch 131 is not limited to channel assignment to the channel strips of the multi-purpose channel strip unit 130, but this point will be described in detail later.

Further, for other parts on the operation panel 100, the selected channel operation unit 141 is a part that collects operators for editing the values of various parameters related to the channel selected by the selection switch 163 shown in FIG. It is.
The level meter 142 is a display that displays the level of the acoustic signal being processed in the part selected by the user in the DSP 16.
The display panel 143 is a display for displaying a screen for displaying the operation content of the digital mixer 10, the setting content in each digital mixer, a GUI for receiving an instruction from the user, and the like.

  The device selection switch 144 is a digital mixer (hereinafter referred to as “edit target device”) that edits the value of a parameter with an operator on the operation panel 100 and displays the setting contents with a display device. Is a switch for selecting from among the digital mixers # 1 to # 3 constituting the. Here, in each of the digital mixers # 1 to # 3, the configuration of signal processing is exactly the same, and the items of parameters that can be set are also the same. Therefore, according to the operation of the device selection switch 144, it is possible to change only the device to be edited without changing the ch and parameter items to be edited by each operator.

  Note that switching of the editing target device according to the operation of the device selection switch 144 is not applied to the operators of the multi-purpose channel strip unit 130 and the ST input channel strip unit 147 (in the multi-purpose channel strip unit 130). This applies exceptionally when the DCA layer is selected, but for the sake of simplicity, this case will not be considered in the following description unless otherwise noted). In addition, the number of mixers that can be cascaded is not necessarily limited by the number of device selection switches 144. For example, a part of the mixers may be assigned to the device selection switch 144, and the remaining mixers may be selected using the controls of the SW groups 145 and 148.

  SW groups 145 and 148 are used to assign setting items to assignable operators, assign channels to ch strips included in the ST input channel strip unit 147 and the master strip unit 149, switch screens to be displayed on the display panel 143, display panel This is a part that collects operators for performing operations on the GUI displayed on 143 and other overall settings of the digital mixer 10.

  The scene control unit 146 is a part that collects operators such as an up / down key for selecting a scene, and a store key and a recall key for instructing to store (save) and recall (read) the selected scene. In the mixer system 1, for each digital mixer, a set of parameter values used for signal processing in the digital mixer is numbered and stored as a scene, and can be stored and recalled at any time by a user operation. It can be performed. When a user operation is performed, a mode in which these stores and recalls are performed on the mixer selected by the device selection switch 144 and a mode in which all digital mixers constituting the mixer system 1 are performed simultaneously are provided. Yes.

  The ST (stereo) input channel strip unit 147 includes two channel strips for editing parameter values used for signal processing in the ST input channel for inputting a stereo sound signal (not shown in FIG. 2). Provided. Also, the digital mixer 10 is provided with 4 ST input channels. Similarly to the input channel strip unit 110 and the like, each channel strip is edited by an operator of the channel strip by the layer (ST input layer). Input channels can be assigned.

  However, the layer selection is performed not on the dedicated layer selection operator but on the GUI displayed on the display panel 143, and not only the channel number assigned to the channel strip but also the editing target device is specified for each layer. This is different from the input channel strip unit 110. The layers prepared for the ST input channel strip unit 147 include a layer for assigning the first and second ST input channels of the digital mixer # 1 to the two channel strips, and the third and fourth ST inputs of the digital mixer # 1. ch, a layer for assigning the first and second ST input channels of digital mixer # 2, a layer for assigning the third and fourth ST input channels of digital mixer # 2, and 1, 2 of digital mixer # 3 There are six layers: a layer to which the third ST input channel is assigned and a layer to which the third and fourth ST input channels of the digital mixer # 3 are assigned.

In addition, the master strip unit 149 is provided with two ch strips for editing parameter values used for signal processing in the ST output channel corresponding to the ST mixing bus, which are not shown in FIG. Since the number of ST output channels is 2 channels, which is the same as the number of channel strips of the master strip unit 149, there is no need to perform allocation by layer. However, which mixer parameter is to be edited by the channel strip is determined according to the operation of the device selection switch 144. In addition, since the ST output channels include C output channels in addition to the LR, it is possible to separately select which parameter of the LR or C of the corresponding ST output channels is to be edited for each channel strip. it can.
One of the characteristic features of the mixer system 1 and the digital mixer 10 is that among the operators provided on the operation panel 100 as described above, the functions of the multi-use ch strip unit 130 and the multi-selectable switch 131 can be selected. This is the contents of the usage layer.

FIG. 7 shows a display example of a layer setting screen for setting the contents of this versatile layer.
This layer setting screen 200 is a GUI and is one of a plurality of screens displayed on the display panel 143 in response to an operation of a predetermined screen selection switch on the operation panel 100. The plurality of screens displayed on the display panel 143 display parameter values and the like corresponding to the screens. The display of each of the display units 201 to 203 and 251 to 256 described below is performed between the screens. Are common.

In the layer setting screen 200, the screen display unit 201 is a part that displays the position of this screen in the hierarchical GUI of the digital mixer 10. The example in the figure shows that this screen is a screen named “FADER ASSIGN” in the “UTILITY” category.
The connected device display unit 202 is a portion that displays devices that are currently cascade-connected to the digital mixer 10 and constitute the mixer system 1. The example in the figure shows that three devices # 1 to # 3 constitute the mixer system 1. Note that which number is assigned to which device may be selected by the user or may be automatically determined. However, it is desirable that the digital mixer having an operation panel capable of controlling the entire mixer system 1 be # 1 (first).

The operation target device display unit 203 is a portion that displays the edit target device selected by the device selection switch 144. The example in the figure indicates that digital mixer # 1 is selected. This editing target device is also displayed as the background color of various screens (including the layer setting screen 200 of course) displayed on the display panel 143 so that it can be visually recognized by the user. For example, if the editing target device is a digital mixer # 1, the background color may be blue gray, if it is # 2, green gray, and if # 3, red gray.
The scene display unit 204 is a part that displays the number and name of the scene currently being edited in the editing target device selected by the device selection switch 144. The example in the figure shows that the scene named “Initial Data” of No. 002 is being edited.

  The layer display unit 210 is a part that displays buttons corresponding to the layer selection switch 131 on the operation panel 100, and also displays which multi-use layer is selected by the layer selection switch 131. The example in the figure shows that the multi-use layer A corresponding to the hatched button is selected. Note that the layer display unit 210 also functions as a row heading indicating which layer is the set content of each row (the cell array in the horizontal direction in the figure) in the adjacent assignment content display unit 220. Needless to say, the selected layer may be displayed by any method such as color, pattern, density, and frame.

  The allocation content display unit 220 is a part that displays the contents of the multi-use layer corresponding to each layer selection switch 131 and receives the editing operation. And the item display part 221 is a column heading which shows the item which can be set in a versatile layer, and the content display part 222 is a part which displays the setting content of a layer. A column is an array of cells in the vertical direction in the figure.

  The items that can be set in the multi-use layer include the designation of the assignment of the channels and the like to the ch strips for 8 ch of the multi-use ch strip unit 130. This is the content set in the column indicated by “1” to “8” in the item display unit 221. For example, the input channel 43 and the output channel 63 shown in FIG. There are certain ST input channels, ST output channels, and monitor output channels. Further, in addition to channels, setting items that do not have a corresponding signal processing element can be assigned, such as eight DCA groups for grouping a plurality of faders to adjust the signal level. In addition, any signal processing element whose level can be adjusted in the digital mixer 10 can be assigned.

In the following description, for the sake of simplicity, the element assigned to the ch strip is assumed to be ch unless otherwise specified. However, the following description applies similarly even when other elements are assigned. It is.
Further, channel assignment by the multi-use layer can be performed by designating not only the channel number but also the device numbers of the devices constituting the mixer system 1. In other words, any channel of any device included in the devices constituting the mixer system 1 can be assigned to the channel strip of the multipurpose channel strip unit 130. This assignment is not changed by the operation of the device selection switch 144.

  In FIG. 7, in the columns indicated by “1” to “8”, the assigned contents of the ch are described in two stages, and “# 1” to “# 3” in the upper part are assigned to the ch strips. For a device including a channel, the character string on the right side indicates the name of the channel assigned to the channel strip. For example, “# 1 CH1” indicates that the first input channel of the digital mixer # 1 is allocated, and “# 2 MIX5” indicates that the fifth output channel of the digital mixer # 2 is allocated. Show. “STx” indicates the xth ST input channel, and “DCAx” indicates the xth DCA group. The names of these channels are fixedly determined and cannot be changed by the user.

  Further, the lower part of the column indicated by “1” to “8” is a character string used for displaying the assigned contents in the display unit 161 of the ch strip to which the ch is assigned according to the layer. This character string can be freely set by the user. For example, it is preferable that the character string has contents that can identify the name and use of the assigned channel. The number of characters is limited to 4 characters in this example due to restrictions on the size of the display.

In addition, as the multipurpose layer information, an editing target device (M_ID), an input ch layer (IN), an output ch layer (OUT), and an ST input layer (STIN) that are simultaneously specified when the multipurpose layer is selected should be set. Can do.
In the digital mixer 10, when the user selects the multi-use layer with the layer selection switch 131, the channel is displayed in the assignment content display unit 220 according to the contents indicated by “1” to “8” in the multi-use ch strip unit 130. At the same time as this assignment, the device to be edited, the input channel layer, and the output channel layer can be selected according to the contents indicated by “M_ID”, “IN”, and “OUT”.
This selection is equivalent to the selection performed by operating the device selection switch 144 and the layer selection switches 111 and 121.

Further, the ST input layer can be selected in accordance with the content indicated by “STIN”. This selection is equivalent to the selection performed by operating the GUI displayed on the display panel 143.
However, the selection of the editing target device and other layers performed according to the selection of the multi-use layer is performed by operating the device selection switch 144 and the layer selection switches 111 and 121 after the multi-use layer is selected. It can be changed regardless of the layer.

  What is set in the items “M_ID”, “IN”, “OUT”, and “STIN” is the designation of the device or layer selected by this function. In the “M_ID” column, the setting contents are displayed by the name of the device to be selected. In the columns “IN”, “OUT”, and “STIN”, the setting contents are displayed by the channel numbers assigned in the layer to be selected.

  Further, for each item shown in the item display unit 221 described above, it is possible to designate “maintain current” as well as some specific assignment contents. In the figure, the location where this designation is made is indicated by "---". Then, even if the multi-use layer is selected, the digital mixer 10 can select the contents of channel assignment to the ch strip, the operation target device, and the items for which “maintain status” is specified in the selected multi-use layer. For the state of the input channel layer and the like, the contents before selection of the multi-use layer are maintained.

  Further, for “1” to “8”, it is possible to specify that no ch is assigned to the ch strip. In the figure, the location where this designation is performed is indicated by “N / A”. When the multi-use layer is selected, the digital mixer 10 does not assign any channel to the channel strip that is designated not to allocate channels. When a channel strip operator without channel assignment is operated, of course, the value of some parameter is not changed according to the operation.

All of the setting contents displayed on the assignment contents display unit 220 as described above can be edited by the SW groups 145 and 148. The DCA layer corresponding to the “DCA” button is a layer to be selected when the multi-use channel strip unit 130 is used as an operator for setting the level of the DCA group. Although this layer is one of the versatile layers, it is different in character from other versatile layers. In this layer, the first to eighth DCA groups are assigned to the eight channel strips, and the other items are fixed with the content of “maintain current state”. There is no cell for displaying and setting the contents.
Also, the content display unit 222 displays the currently selected layer in the same manner as the layer display unit 210. In the example of the figure, the multi-use layer A corresponding to the hatched row is selected. It shows that.

  In the layer setting screen 200, the fader display unit 231 is provided corresponding to the columns “1” to “8” of the item display unit 221. Then, for the ch strip corresponding to each column of the multi-use ch strip unit 130, the position of the knob on the fader operation element 165 included in the ch strip is displayed. This display is updated according to the operation of the fader operator 165. Also, an allocated channel display unit 232 is provided below the fader display unit 231, and information indicating the channel allocated to the corresponding channel strip is displayed using a display character string set in the content display unit 222. Is displayed.

The master function display unit 240 is a part that displays which parameter of LR or C is edited for each ST output channel by the two channel strips of the master strip unit 149.
The selected channel display unit 251 is a part that displays information on the channel selected by the selection switch provided in the channel strip.

  The knob & fader function display unit 252 is a part that displays functions assigned to the rotary encoder 162 and the fader operation unit 165 provided in the ch strip of the multipurpose ch strip unit 130. In the figure, the upper side shows the function of the rotary encoder 162, and the lower side shows the function of the fader operator 165. The example shown in the figure shows that the rotary encoder 162 is assigned a send level to the first mixing bus 44 and the channel fader is assigned to the fader operator 165.

The input channel layer display unit 253 is a part that displays the currently selected input channel layer by the input channel number assigned to the input channel strip unit 110. The example in the figure shows that the input channel layer to which the 33rd to 48th input channels are assigned is selected.
The output channel layer display unit 254 is a part that displays the currently selected output channel layer by the number of the output channel assigned to the output channel strip unit 120. The example in the figure shows that the output channel layer to which the 9th to 16th output channels are allocated is selected.
The multipurpose layer display unit 255 is a part for displaying the currently selected multipurpose layer. The example in the figure shows that the multi-use layer A is selected.

The ST input layer display unit 256 is a part that displays the currently selected ST input layer by the device assigned to the ST input channel strip unit 147 and the ST input channel number. The example in the figure shows that the ST input layer to which the first and second ST input channels of the digital mixer # 1 are assigned is selected.
The display of each of the layer display units 253 to 256 is changed when a corresponding layer is newly selected. This change is also made when an input channel layer or the like is selected in accordance with the selection of the versatile layer.

  The user of the mixer system 1 can set the contents of the multipurpose layer by referring to various setting contents on the layer setting screen 200 as described above. The layer information that is the setting content is stored in the current memory as part of the current data, and is saved as part of the scene when the scene is saved.

Further, it is sufficient that the layer information is stored only in the current memory of the digital mixer # 1 having the operation panel 100. However, here, other digital mixers can perform signal processing independently without being cascade-connected to the digital mixer # 1. For this reason, all the digital mixers # 1 to # 3 constituting the mixer system 1 are provided with the same type of current memory. Therefore, layer information is also stored in all the digital mixers # 1 to # 3. Therefore, when different scenes are recalled for each mixer, the layer information may be different between the mixers.
However, when the mixer system 1 is operated, for example, the mixer having the operation panel 100 is designated as the master device, and the layer information stored in each mixer is always matched with the layer information stored in the master device. It is possible to prevent problems caused by

  Meanwhile, another characteristic point of the mixer system 1 and the digital mixer 10 is that the cascade link function described with reference to FIGS. 2 to 4 and the cascade bus 52 of the same system when performing the cascade link. This is an output channel link function for linking parameters between output channels to which acoustic signals are supplied.

FIG. 8 shows a display example of a cascade link setting screen for accepting settings related to the cascade link and the output channel link.
The cascade link setting screen 300 shown in this figure is a GUI displayed on the display panel 143. However, in the figure, only the display content of the portion sandwiched between the displays corresponding to the display units 201 to 203 and 251 to 256 shown in FIG. 7 in the screen displayed on the display panel 143 is shown.

The cascade link setting screen 300 includes a cascade system display unit 310, an output channel link setting button 320, a bus setting unit 330, a cascade link setting button 340, and a device selection button 350.
The cascade system display unit 310 shows the system of the cascade buses 51 and 52 shown in FIG. 2. On the cascade link setting screen 300, the output channel link setting button 320, the bus setting unit 330, The setting by the cascade link setting button 340 is accepted.

  Among these, the bus setting unit 330 is a part for setting the mixing bus 44 that adds the output acoustic signal to the cascade buses 51 and 52 of each system. Only one mixing bus 44 can be set for one system, and one mixing bus 44 can be set for only one system. Therefore, the system and the mixing bus 44 basically have a one-to-one correspondence. In addition, this setting may be considered to set the output source mixing bus 44 for each system of the cascade buses 51 and 52, or set the output destination cascade buses 51 and 52 for each mixing bus 44. Then you can think.

  It is not always necessary to set the mixing bus 44 for all the systems (refer to the MX11 and MX12 systems in the figure). The acoustic signal mixed by the mixing bus 44 not set for any system is not added to the cascade bus 51 but is supplied to the corresponding output ch 63 as it is.

  The cascade link setting button 340 sets whether or not the cascade ON switch 46 corresponding to the mixing bus 44 set in the bus setting unit 330 is turned on / off, that is, whether or not an acoustic signal is added from the mixing bus 44 to the cascade bus 51. It is a button for. For systems in which the mixing bus 44 is not set, the cascade link is always off.

  The setting by the bus setting unit 330 and the cascade link setting button 340 can be performed for each mixer. The device selection button 350 is a button for selecting a mixer to be set. When this button is operated, the display of the bus setting unit 330 and the cascade link setting button 340 displays the setting contents in the newly selected mixer. Updated to indicate The example in the figure shows that the parameters related to the digital mixer # 2 selected by the hatched button are set.

  The output channel link setting button 320 keeps the parameter values of the output channels 63 to which the acoustic signals are supplied from the cascade bus 52 in the mixer system 1 at the same value for each system cascade bus 52 (link). This is a button for setting whether or not to perform output channel linking. Note that ON / OFF of the output channel link is a common setting for all mixers, and even if the selection of the mixer is changed by the device selection button 350, the display of the output channel link setting button 320 does not change.

  In the mixer system 1, the output channel for linking parameter values can be set on the basis that the acoustic signal is supplied from the same cascade bus 52 as described above, and therefore, from one cascade bus 52. Even when the same acoustic signal is supplied to output channels of different numbers by the mixer, the parameters of those output channels can be linked by a simple operation. When such a link is performed, the output channels 63 to which the same acoustic signal is supplied perform signal processing using the same parameter values, and therefore the same output acoustic signal can be obtained from these output channels 63. .

In the mixer system 1, for each mixer, the acoustic signals output from the mixing bus 44 having different numbers can be added by one cascade bus 51, thereby increasing the degree of freedom of the cascade link. However, on the other hand, the addition result may also be supplied to output channels with different numbers for each mixer, and the correspondence between these output channels is slightly difficult to understand.
However, as described above, since the output channels that link the parameter values can be set on the basis of the range of the output channels to which the acoustic signal is supplied from the same cascade bus 52, one cascade bus is provided. Even when the acoustic signal output from 52 is supplied to output channels having different numbers for each mixer, the link between the output channels to which the same acoustic signal is supplied can be easily and appropriately set.

  For the above purpose, even if the output channel 63 corresponds to the mixing bus 44 in which the output channel link is set to ON, the output channel 63 corresponding to the mixing bus 44 in which the cascade link is set to OFF is used. Do not link parameter values. This is because such an output channel 63 is not supplied with an acoustic signal from the cascade bus 52, and therefore has no meaning to be linked.

  Further, FIG. 8 shows a screen for accepting setting of a cascade link and an output channel link related to an audio signal mixed by 24 monaural mixing buses 44. To enable cascade link and output channel link for other buses such as ST bus and AUX bus, prepare screens for accepting settings related to these buses. The processing for realizing the cascade link and the output channel link may be performed according to the setting content received here.

Here, FIG. 9 shows an example of data set on the cascade link setting screen 300.
As shown in this figure, the setting contents related to the cascade link and the output channel link are as follows. First, the output channel link on / off, which is a setting common to all the mixers, regarding the ID (LINE ID) of each system of the cascade buses 51 and 52. (OUTPUT CH LINK). Further, as settings for each mixer, the ID of the mixing bus 44 (BUS) that supplies the acoustic signal to the cascade bus 51 of the system, and whether or not the acoustic signal is actually supplied to the cascade bus 51 (CASCADE LINK) There is a setting.
These data are stored in the current memory as data common to each digital mixer, but when storing or recalling a scene, it is not included in the scene and is read and written, but can be stored and recalled separately from the scene. ing.

  For example, when the data shown in FIG. 9 is stored in the current memory, the output channel link related to the cascade bus of the MX1 system is the fifth output channel of the digital mixer # 1 and the third channel of the digital mixer # 2. Are linked to the first output channel of the digital mixer # 3. In this case, when the parameter value of one of the output channels is changed, the same change is automatically made for the parameters of the other two output channels.

  As for the output channel link related to the cascade bus of the MX2 system, since the cascade link is off in the digital mixer # 2, the fourth output channel of the digital mixer # 1 and the second output of the digital mixer # 3 Link only ch. For the MX3 system cascade bus, since the output channel link is off, no link is performed for any output channel.

  When a new output channel link is started, the link may be started after copying the parameters of any one of the output channels to be linked to the output channel to be linked. For example, it is conceivable to copy the parameter of the output channel of the youngest digital mixer. When a new output channel to be linked is added to a link that is already being executed, the parameters of any output channel that is being linked may be copied to the newly added output channel.

  As is apparent from the above description, in the mixer system 1, the user operates the operation panel 100 of the digital mixer # 1 so that all the digital mixers constituting the mixer system 1 are processed. Can set parameter values used for signal processing, and store and recall scenes. That is, the user can remotely control the other digital mixers # 2 and # 3 using the digital mixer # 1.

Next, the configuration for realizing this remote control and the operation of each digital mixer will be described.
FIG. 10 is a diagram for explaining the remote control function.
As shown in this figure, in the mixer system 1, the digital mixer # 1 is first provided with a current memory 81 (81A) for storing parameter values used by the digital mixer # 1 for signal processing. The scene memory 82 provided in the memory 12 can be stored, or the contents of the scene stored in the scene memory 82 can be recalled to the current memory 81A.

  When the contents of the current memory 81A are changed, the digital mixer # 1 immediately supplies the contents to the signal processing control unit 83, and the signal processing control unit 83 sets the DSP 16 based on the changed parameter values. A coefficient to be obtained is obtained, and the coefficient is set in an appropriate register of the DSP 16 and reflected in the contents of signal processing. Accordingly, the contents of the current memory 81A are reflected in the signal processing in the DSP 16 in real time.

FIG. 11 shows a flowchart of processing executed by the CPU 11 when the contents of the current memory 81A change.
The CPU 11 functions as the signal processing control unit 83 by executing the processes of steps S11 and S12 when the contents of the current memory 81A change.
Here, the reason why the contents of the current memory 81A are not set in the DSP 16 as they are is because there are parameters that affect the values of other parameters, such as the level of the DCA group.

In the mixer system 1, each digital mixer has the current memory 81, the scene memory 82, and the signal processing control unit 83 as described above, and stores and recalls scenes alone, and stores the contents of the current memory 81. This can be reflected in signal processing in the DSP 16.
Further, the digital mixer # 1 has a function of changing the contents of the current memory 81 or displaying the contents of the current memory 81 on the operation panel 100 by an operation from the operation panel 100. Such an operation can be performed sufficiently quickly for the current memory of the own device.

  However, when the digital mixer # 1 accesses the current memories of the other digital mixers # 2 and # 3, a data transmission delay occurs. For this reason, it is difficult to reflect the change in the current memory 81 of the digital mixers # 2 and # 3 according to the operation of the operation panel 100 to the display sufficiently quickly.

  Therefore, the digital mixer # 1 is also provided with current memories 81B ′ and 81C ′ for storing parameter values used by the digital mixers # 2 and # 3 for signal processing, and the contents of the current memory are changed according to the operation of the operation panel 100. Is temporarily performed on the current memories 81B 'and 81C'. The operation panel 100 is also displayed based on the contents of the current memories 81B 'and 81C'.

  Such an access to the current memories 81B 'and 81C' by the digital mixer # 1 can be performed using a common program because the memory address is merely different from that for the access to the current memory 81A. . Therefore, the same operational feeling as viewed from the user can be obtained when editing the contents of the current memory 81A and when editing the contents of the current memories 81B ′ and 81C ′.

  On the other hand, changes made to the current memories 81B 'and 81C' are quickly digitalized by the current synchronization processing unit 85 on the digital mixer # 1 side and the current synchronization processing unit 86 on the digital mixer # 2 and # 3 side. Reflected in the current memories 81B and 81C provided in the mixers # 2 and # 3, the contents of the current memories 81B 'and 81C' and the contents of the current memories 81B and 81C are matched, and the stored contents are synchronized between these memories. Like to take. Accordingly, changes made to the current memories 81B ′ and 81C ′ are also reflected in signal processing in the digital mixers # 2 and # 3. This reflection causes a delay corresponding to the transmission delay, but from the viewpoint of real-time operation, it is not as important as the display delay.

FIG. 12 shows a flowchart of processing executed by the CPU 11 of the digital mixer # 1 and the digital mixer # 2 or # 3 when the contents of the current memory 81B ′ or 81C ′ change.
When the contents of the current memory 81B ′ or 81C ′ change, the CPU 11 of the digital mixer # 1 starts the processing shown in the flowchart on the left side of FIG. 12, and the change contents of the parameters are associated with the changed current memory. The digital mixer corresponding to the digital mixer to be notified is notified (S21).

  Upon receiving this notification, the CPU 11 of the digital mixer # 2 or # 3 starts the processing shown in the flowchart on the right side of FIG. 12, reflects the notified change in its own current memory (S31), and notifies it. A response is transmitted to the original (S32). Then, as in the case of the process of FIG. 11, a signal processing coefficient corresponding to the changed parameter value is obtained and set in the DSP 16 (S33, S34), and the process is terminated.

On the other hand, the digital mixer # 1 stands by until a response is received from the notification destination in step S21 (S22), and thereafter, if the received response is not an error response (S23), the process is terminated. If it is an error response, an error process is performed (S24) and the process is terminated.
The CPU 11 of the digital mixer # 1 functions as the current synchronization processing unit 85 through the above processing. The CPUs 11 of the digital mixers # 2 and # 3 function as the current synchronization processing unit 86 and the signal processing control unit 83 by the above processing.

Next, processing related to scene store / recall will be described.
For example, when a scene is stored in the digital mixer # 2, the contents of the current memory 81B on the digital mixer # 2 side are simply stored in the scene memory 82 of the digital mixer # 2. Therefore, it is not necessary to modify the contents of the current memory 81B ′ on the digital mixer # 1 side.
However, when a scene is recalled by the digital mixer # 2, it is necessary to copy the contents of the scene to be recalled to the current memory 81B 'on the digital mixer # 1 side. In this case, if the scene data is transferred from the digital mixer # 2 to the digital mixer # 1 after the recall is instructed, the transfer takes time.

Therefore, when the scene of the recall candidate selected by the up / down button or the like is displayed on the operation panel 100, the digital mixer # 1 transmits the information to the digital mixer # 2, and from the scene memory 82 of the digital mixer # 2. The displayed scene data is read out, transferred to the digital mixer # 1, and stored in the scene buffer 84. When data is actually copied from the scene buffer 84 to the current memory 81B ′ when the recall instruction is actually issued, the scene can be recalled promptly. The recall on the digital mixer # 2 side may be performed by transmitting a recall instruction to the digital mixer # 2 and in response to the instruction. The scene buffer 84 can be provided in the RAM 13.
In the mixer system 1, each digital mixer is provided with the above functions, so that the operation of the other digital mixers # 2 and # 3 can be comfortably remote controlled using the operation panel 100 provided in the digital mixer # 1. can do.

Next, processing executed by the CPU 11 to realize the functions such as operation target device selection, layer selection, multi-use layer selection, parameter editing using the layer, and output channel link described above will be described.
Table 1 shows a list of main registers and parameters used in the processing described below. The registers and parameters shown in this table are stored in the current memory. When “Independent for each device” is “O”, the values relating to each of the digital mixers # 1 to # 3 are assigned to the current memory of each device. Store values separately and reference them separately. In the case of “x”, a common value for the digital mixers # 1 to # 3 is stored in the current memory of the digital mixer # 1 and is referred to. However, in order to make the format of the current memory common, the digital mixer # 2 , # 3, the same value as the digital mixer # 1 is stored.

First, FIG. 13 shows a flowchart of processing executed by the CPU 11 of the digital mixer # 1 when the device selection switch 144 is operated.
When the device selection switch 144 is operated on the operation panel 100, the CPU 11 of the digital mixer # 1 starts the process shown in the flowchart of FIG. First, the number of the operation target device corresponding to the operated switch is set in the target device register TM (S41). Thereafter, display and operation in the input channel strip unit 110, the output channel strip unit 120, and the master strip unit 149 based on the newly set TM value and the register value indicating the layer currently selected in each strip unit. The position of the child and the display on the display panel 143 are changed to the contents relating to the TM-th device (S42), and the process ends.

There is a channel strip that displays information about the allocated channel and the operation target device and parameter values by using a small display, LED, etc., which is changed in step S42. It is a display. Further, the operator whose position is changed in step S42 has a driving means like the electric fader 102, for example, and should adjust the position of the knob to the value of the parameter. With respect to the processing shown in other flowcharts, the display in the ch strip section and the change of the position of the operation element have the same meaning.
With the processing in FIG. 13, the operation target device can be switched according to the operation of the device selection switch 144. In this processing, the CPU 11 functions as a mixer selection unit.

Next, FIG. 14 shows a flowchart of processing executed by the CPU 11 of the digital mixer # 1 when the layer selection switch 111 for selecting the input channel layer is operated.
When the layer selection switch 111 is operated, the CPU 11 of the digital mixer # 1 starts the process shown in the flowchart of FIG. First, the input channel layer number corresponding to the operated switch is set in the input channel layer register IL (S51).

Thereafter, based on the newly set IL value, the display and the position of the operation element on the input channel strip unit 110 and the display on the display panel 143 are changed to the contents relating to the newly selected layer (S52). The process ends.
With the above processing, the input channel layer, which is the first layer, can be switched in accordance with the operation of the layer selection switch 111. In this processing, the CPU 11 functions as first layer selection means.

Next, FIG. 15 shows a flowchart of processing executed by the CPU 11 of the digital mixer # 1 when the fader of the input channel strip unit 110 is operated.
The CPU 11 of the digital mixer # 1 starts the processing shown in the flowchart of FIG. 15 when any channel strip fader (or an operator assigned with a fader parameter) is operated in the input channel strip unit 110.

First, the layer information of the currently selected IL-th input channel layer is referenced, and the input channel number assigned to the channel strip including the operated fader in that layer is set in the variable ic ( S61).
Thereafter, the fader level IFL (ic) of the ic-th input channel in the current memory for the TM-th device is changed to a value Fvol obtained by converting the position of the fader after the operation into decibels (S62). In response to this, the display on the input channel strip unit 110 and the display panel 143 is changed to one corresponding to the contents of the changed current memory (S63).

  Further, when there is a channel strip to which the ic-th input channel of the TM-th device is assigned in the multi-use channel strip unit 130 (S64), the fader level changed in step S62 is also displayed in this channel strip. Therefore, the position of the fader operator in the corresponding channel strip is changed to one corresponding to the contents of the current memory after the change (S65), and the process is terminated. If “NO” in the step S64, the process is ended as it is.

According to the above processing, according to the operation of the fader of the input channel strip unit 110, the parameters of the input channel assigned to the channel strip including the fader can be edited by the selected input channel layer. Of course, the same editing can be performed even when an operator other than the fader is operated. In this process, the CPU 11 functions as parameter editing means.
In the multi-use channel strip unit 130, when a parameter other than the channel fader is assigned to the fader operator 165, and the fader level value is not displayed by the position of the operator, the display, or the like, Steps S64 and S65 need not be performed. The same applies to the processes shown in the following flowcharts.

  By the way, when the process of step S62 in FIG. 15 is performed, as a result, the contents of the current memory change. As described above, the CPU 11 executes the process of FIG. The contents of the subsequent current memory are reflected in the signal processing in the DSP 16.

Here, as a specific example of the processing shown in steps S11 and S12 of FIG. 11 and steps S33 and S34 of FIG. 12, FIG. 16 is a flowchart of processing for reflecting the change of the fader level of the input channel in the signal processing in the DSP 16. Show.
This process is executed by the CPU 11 of the TMth digital mixer whose parameter value has been changed. When the CPU 11 detects that the fader level IFL (ic) of the input channel has changed in its own current memory, the CPU 11 starts the processing shown in the flowchart of FIG.

  First, the value of IFL (ic) is stored in the volume register vol (S71), and 1 is set in the counter d (S72). Thereafter, when the ic-th input channel belongs to the d-th DCA group, the process of adding the fader level DL (d) of the d-th DCA group to vol is performed while increasing d by 1 while d = Repeat from 1 to 8 (S73 to S76).

Note that DL (d) is a decibel value and may be a negative value. The DCA group is defined for each mixer. Then, by the processing of steps S73 to S76, the value of vol can be made a value obtained by adding the fader level of each DCA group to the fader level of the input channel.
Therefore, next, a multiplication coefficient corresponding to the value of vol is obtained and set in the DSP 16 as a value used for signal processing of the ic-th input channel (S77), and the processing ends.
With the above processing, the CPU 11 can reflect the content of the current memory after the change in the signal processing in the DSP 16.

Next, FIG. 17 shows a flowchart of processing executed by the CPU 11 of the digital mixer # 1 when the layer selection switch 121 for selecting the output channel layer is operated.
When the layer selection switch 121 is operated, the CPU 11 of the digital mixer # 1 starts the process shown in the flowchart of FIG. First, the number of the output channel layer corresponding to the operated switch is set in the output channel layer register OL (S81).

Thereafter, based on the newly set OL value, the position of the display and operation element in the output channel strip unit 120 and the display on the display panel 143 are changed to the contents related to the newly selected layer (S82). The process ends.
With the above processing, the output channel layer, which is the first layer, can be switched in accordance with the operation of the layer selection switch 121. In this processing as well, the CPU 11 functions as first layer selection means.

Next, FIGS. 18 and 19 are flowcharts of processing executed by the CPU 11 of the digital mixer # 1 when the fader of the output channel strip unit 110 is operated.
The CPU 11 of the digital mixer # 1 starts the process shown in the flowchart of FIG. 18 when any one of the channel strip faders (or the operator assigned the fader parameter) is operated in the output channel strip unit 120.

First, the layer information of the currently selected OL-th output channel layer is referenced, and the number of the input channel assigned to the channel strip including the operated fader in that layer is set in the variable oc ( S91).
Thereafter, the fader level OFL (oc) of the oc-th output channel in the current memory for the TM-th device is changed to a value Fvol obtained by converting the fader position after the operation into decibels (S92). In response to this, the display on the output channel strip unit 120 and the display panel 143 is changed to one corresponding to the contents of the changed current memory (S93).

Further, when there is a ch strip to which the oc-th output channel of the TM-th device is assigned in the multi-use ch strip unit 130 (S94), the position of the fader operator in the corresponding ch strip is changed to the current memory after the change. (S95).
The processing up to this point is the same as the processing shown in FIG. 15 although there is a difference between the input channel and the output channel. The processes after step S96 are processes for realizing the output channel link function.

  In this part of the process, first, in the cascade bus of the system set to the mixing bus corresponding to the oc-th output channel of the TM-th device, the output channel link set on the screen shown in FIG. 8 is ON. If there is (S96), the system number is set in the variable LN (S97). Thereafter, if the cascade link set on the screen shown in FIG. 8 is ON for the mixing bus corresponding to the oc-th output channel of the TM-th device (S98), OFL (oc) in step S92. In order to reflect the change in the value to other output channels to be linked, the process proceeds to step S99 in FIG.

  On the other hand, if “NO” in the step S96, the setting is made so as not to perform the output ch link, so the process is ended as it is. If NO in step S98, it can be seen that an acoustic signal that is not cascade-linked is input to the output channel whose fader level has been changed this time. Also in this case, since there is no need to perform output channel link, the processing is terminated as it is.

  Next, in the processing of the part shown in FIG. 19, first, the number of any one of the digital mixers constituting the mixer system other than the editing target device indicated by TM is set in the variable TM ′ (S99). . In the subsequent step S108, the numbers of all the devices other than the device to be edited are sequentially set to TM ′, so that any device number may be set here. For example, the candidate with the smallest number may be used.

In the TM′-th device, if there is a mixing bus in which the LN-th system set in step S97 is set (S100), and the cascade link of the mixing bus is ON (S101), the variable oc 'Is set to the number of the output channel corresponding to the mixing bus (S102).
In this case, the oc-th output channel of the TM-th device and the oc'-th output channel of the TM′-th device are in a relationship of being supplied with the same acoustic signal from the same cascade bus. Therefore, the change made in step S92 in FIG. 18 is also reflected in the fader level OFL (oc ') of the oc'th output channel of the TM'th device so that the parameter values in these channels are kept the same. In the current memory of the TM′th device, the value of OFL (oc ′) is changed to the same Fvol as in step S92 (S103).

Thereafter, the display and the position of the operator are changed to the same meaning as in steps S93 to S95 in FIG. 18 (S104 to S106). If there is still a candidate for TM ′, the next candidate is set in TM ′ (S107, S108), and the process returns to step S100 to repeat the process. If NO in step S107, the process ends.
If NO in step S100 or S101, the TM′-th device does not supply an acoustic signal to the output channel from the LN-th system cascade bus, so there is no output channel to be linked. It will be. Therefore, the process immediately proceeds to step S107, and if there is still a candidate for TM ′, the next candidate is set for TM ′.

  With the above processing, the output channel parameters corresponding to the selected output channel layer can be edited in accordance with the fader operation of the output channel strip unit 120. And in the process of step S91, S92 for this, CPU11 functions as a parameter edit means.

  Further, when the parameter value of a certain output channel is changed in a certain digital mixer, the parameter value of the output channel that is an output channel of another digital mixer and to which an acoustic signal is supplied from the same cascade bus as the certain output channel is described. The same change can be made to the values, and the parameters defining the signal processing contents in these output channels can be kept at the same value. That is, the output channel link function described with reference to FIGS. 8 and 9 can be realized. And in the process of step S96-S103 for this, CPU11 functions as a parameter link means.

  When the contents of the current memory change due to the processing in step S92 or S101, the CPU 11 of the corresponding digital mixer performs the same processing as in FIG. 16 and sets the DCA group to the fader level of the output channel after the change. Although the value in consideration of the contents is reflected in the signal processing in the DSP 16, illustration of this processing is omitted.

Next, FIGS. 20 and 21 show flowcharts of processing executed by the CPU 11 of the digital mixer # 1 when there is an operation of the layer selection switch 131 for selecting the multi-use layer.
When the layer selection switch 131 is operated, the CPU 11 of the digital mixer # 1 starts the process shown in the flowchart of FIG.

  First, the number of the multi-use layer corresponding to the operated switch is set in the multi-use layer register fm (S111). After that, referring to the layer information of the multipurpose layer set on the layer setting screen 200 shown in FIG. 7, if the designation of the operation target device is not maintained in the fm-th multipurpose layer (S112), the target device The number of the operation target device specified in the fm-th multipurpose layer is set in the register TM (S113), and the operation target device of that number is selected. Further, if the operation target device designation is the current state maintenance in step S112, the value of the target device register TM, that is, the selected content of the operation target device is maintained without being changed.

  In either case, the process proceeds to the next process. Then, for each item of the input channel layer, the output channel layer, and the ST input channel layer, if the current status maintenance is not specified in the fm-th multi-use layer, the input channel layer register IL is determined according to the specification content in the multi-use layer. , Output channel layer register OL and ST input channel layer register SIL are set, and each layer is selected. If the current status is designated, the item is maintained without changing the layer selection (S114 to S119).

Thereafter, the process proceeds to step S121 in FIG. 21, and 1 is set to the variable i (S121), and it is determined whether fm = 7 (S122). Note that fm = 7 means that the DCA layer has been selected by the layer selection switch 131.
If fm = 7, the value of TM indicating the currently set operation target device is set in the register TM (i) indicating the operation target device by the i-th fader of the multi-use channel strip unit 130. The ID (identification information) indicating the fader of the i-th DCA group is set in the register TF (i) indicating the channel assigned to the i-th fader (S123).

  On the other hand, if fm = 7, the layer information of the selected multi-use layer is referred to, and it is determined whether or not the channel assignment for the i-th fader is maintained in the fm-th multi-use layer (S124). . If the current state is not maintained, fm is stored in the register TM (i) indicating the operation target device by the i-th fader of the multi-purpose channel strip unit 130 and the register TF (i) indicating the assigned channel for the i-th fader, respectively. The operation target device designated for the i th fader in the th multi-use layer and the ID of the assigned channel are set (S125). If the current state is maintained, the setting contents of the operation target device and the assigned channel in the i-th fader are maintained without being changed.

  As the ID set in the register TF (i) in steps S123 and S125, an ID that can uniquely identify all the elements such as ch and DCA group that can be assigned to the ch strip of the multipurpose ch strip unit 130 is used. In the layer information, the assigned channel may be described by this ID. Also, an ID indicating no allocation is prepared, and when it is set that the channel is not allocated in the multi-use layer, the ID without allocation is set to TF (i). The contents of TF (i) are allocation information.

  After steps S123 and S125, i is incremented by 1 (S126). If i is 8 or less (S127), the process returns to step S122 and the process is repeated. Therefore, by the processing in steps S121 to S127, the operation target device and the channel assignment can be set for each of the eight channel strips of the multi-use channel strip unit 130 based on the layer information of the selected multi-use layer.

  Thereafter, when NO is determined in step S127, the input channel strip unit 110, the output channel strip unit 120, and the multi-use are based on the value of fm and the layer, operation target device, and allocated channel information set in the processing so far. The positions of the display and operation elements in the channel strip unit 130, the ST input channel strip unit 147, and the master strip unit 149 and the display on the display panel 143 are updated (S128), and the process is terminated.

  With the above processing, the multi-use layer, which is the second layer, can be switched in accordance with the operation of the layer selection switch 131, and in this processing, the CPU 11 functions as a second layer selection means. The CPU 11 functions as a mixer selection unit in step S113 for designating an operation target device, and functions as a layer selection unit in steps S115, S117, and S119 for selecting a layer in another channel strip unit.

  In this case, for channel strips for which the current status is designated in the layer information, the allocation of channels before switching can be maintained even when the versatile layer is switched. In addition, any channel can be not assigned to a channel strip in which it is specified in the layer information that channels are not allocated. Accordingly, it is possible to obtain a high degree of freedom in channel assignment using layers.

  In addition, not only the channels included in the digital mixer # 1 having the operation panel 100 but also any channels of any device constituting the mixer system 1 can be assigned to the channel strips of the multipurpose channel strip unit 130. Therefore, high operability can be obtained even when parameters of a plurality of mixers are edited simultaneously.

  Furthermore, simultaneously with the channel assignment, it is possible to select a layer indicating the channel assignment to the operation target device by the operation panel 100 and other channel strip units. Of course, the current situation can be maintained for this selection. Therefore, high operability is obtained when assigning channels to the operators of a plurality of sections at the same time, such as when assigning a channel deeply related to the channel assigned to the multi-use channel strip unit 130 to another channel strip unit. be able to.

Next, FIGS. 22 and 23 show flowcharts of processing executed by the CPU 11 of the digital mixer # 1 when the fader of the multipurpose channel strip unit 130 is operated.
When the fader of any ch strip (or an operator assigned with a fader parameter) is operated in the multipurpose ch strip unit 130, the CPU 11 of the digital mixer # 1 starts the processing shown in the flowchart of FIG.

First, the operated fader number is set in the variable i (S131). Thereafter, a target indicated by TF (i), that is, a target to be operated by the operated fader is determined (S132), and processing corresponding to the type of the target is performed.
First, if the target is an input channel, the number of the input channel indicated by TF (i) is set in the variable ic (S133), and the input fader level setting process shown in steps S62 to S65 of FIG. 15 is performed. (S134), the process ends. By this processing, the fader level of the input channel assigned to the operated fader can be changed according to the operation of the fader, and the display contents and the position of the operation element can be updated. Since the operation target device by the i-th fader is set in the register TM (i), the value of TM (i) is used instead of TM in the input fader level setting process.

  If the target is an output channel in step S132, the output channel number indicated by TF (i) is set in the variable oc (S135), and the outputs shown in steps S92 to S108 of FIGS. A fader level setting process is performed (S136), and the process ends. By this process, the fader level of the output channel assigned to the operated fader and the output channel linked to this can be changed according to the operation of the fader, and the display content and the position of the operation element can be updated. . In the output fader level setting process, the value of TM (i) is used instead of TM.

If there is no assignment in step S132, the process ends without changing the parameter value according to the fader operation.
If it is determined in step S132 that the target is a DCA group, the processing from step S141 onward in FIG. 23 is performed.

  First, the DCA group number indicated by TF (i) is set in the variable d (S141). Thereafter, the fader level DL (d) of the d-th DCA group in the current memory for the TM (i) -th device is changed to a value Fvol obtained by converting the position of the fader after the operation into decibels (S142). The display on the use channel strip unit 130 and the display panel 143 is changed to one corresponding to the changed contents of the current memory (S143).

Next, it is determined whether or not the d-th DCA group cascade link is ON (S144). In the mixer system 1, as described above, the DCA group is provided for each device, but the cascade link of the DCA group is a function for setting the same fader level of the DCA group of the same number in all devices. The cascade link is a common setting for all devices, and can be set to ON / OFF for each DCA group.
If the cascade link is not ON in step S144, it is not necessary to change the parameter values for other items, so the processing returns to FIG. However, if it is ON, the setting processing related to the DCA group of the other device in step S145 and subsequent steps is performed.

In this process, devices other than the device indicated by TM (i) are sequentially selected (S145, S150, S151), and the value of fader level DL (d) of the d-th DCA group is set in the current memory for each device. The same Fvol as in step S142 is set (S146). Further, the display on the display panel is updated (S147), and when the DCA group whose fader level is changed is assigned to the ch strip of the multipurpose ch strip unit 130, the DCA operator of the corresponding ch strip is updated. The position is also updated (S148, S149).
When these processes are completed for all devices, the process returns from step S150 to FIG. 22 and ends.

If it is another target in step S132 of FIG. 22, processing corresponding to the target is performed (S137), and the change of the fader level of the target assigned to the operated fader is changed, or accordingly. Update the display. For example, the case where an ST input channel, an ST output channel, a monitor output channel, and the like are assigned corresponds to this case.
According to the above processing, according to the operation of the fader of the multipurpose ch strip unit 130, the target parameter assigned to the ch strip including the fader can be edited according to the multipurpose layer. Also in this process, the CPU 11 functions as parameter editing means.

  When the fader level of the DCA group is changed by the processing in steps S142 and S146, the coefficients to be reflected in the signal processing of the DSP 16 change for all the channels belonging to the DCA group. Therefore, in this case, the CPU 11 of each digital mixer that has changed the fader level of the DCA group performs the processing shown in FIG. 16 for all the channels belonging to the DCA group, and follows the changed fader level value. Reset the coefficients to DSP.

This is the end of the description of this embodiment, but it goes without saying that the system configuration, apparatus configuration, data configuration, specific processing contents, and the like are not limited to those described in the above-described embodiment.
For example, it goes without saying that the number, type, function, and the like of channels and buses provided in each digital mixer are not limited to those of the above-described embodiment. The same applies to the number and function of ch strip portions provided in the operation panel and the number of ch strips provided in each ch strip portion. Regarding the number of cascade buses, the example in which the same number of mixing buses is provided for each type of mixing bus has been described. However, the number of cascade buses is not limited to this, and may be more or less than the number of mixing buses.
Further, as a correspondence relationship between the mixing bus and the cascade bus, a predetermined relationship may be used instead of the one set by the user on the screen of FIG.

Further, the number of input channels and output channels does not necessarily have to be common among the digital mixers constituting the mixer system.
If the number of channels is different between one mixer and another mixer, when the editing target device is switched, the channel assigned to the channel strip does not exist in the switched mixer or the selected layer is It may be possible that the mixer does not exist after switching. However, for the channel strip where a non-existent channel is assigned or the channel strip portion where a non-existent layer is selected, the parameter corresponding to the operation of the operator is set as in the case where no channel is assigned. If the value is not changed, there will be no problem in operation. In addition, instead of a non-existing channel or layer, another channel or layer existing in the editing target device may be automatically selected, or selection of a channel or layer before switching may be maintained.

  A similar situation may also occur when the second or third digital mixer corresponding to the device selection switch 144 is not cascade-connected to the digital mixer having the operation panel 100. However, in this case as well, it is possible not to change the parameter value according to the operation of the operation element for the operation element for which the mixer parameter that does not exist is used for the operation by selecting the editing target device. It may be possible to select another existing mixer as the editing target device instead of the non-existing device, or keep the editing target device unchanged without changing the editing target device. It is done.

Further, in the description of the embodiment, the expression “number of ch” or the like is used. However, this “number” may be any number as long as it can identify a specific ch or the like from other ch or the like of the same function. Good. Therefore, even if arbitrary identification information including characters, symbols, and the like is used in place of “number”, processing similar to that described in the above-described embodiment is possible.
Further, regarding the output channel link function, the above-described embodiment has described the example in which the output channel link is turned on / off for each system. However, an output channel link may be set for each of a plurality of systems in units of a plurality of systems, and all output channels that supply acoustic signals from any of the cascade buses may be linked. Such a function can be effectively used when two monaural buses are set to process a stereo L signal and an R signal.

In addition, the various functions described in the above-described embodiments are not provided at the same time, and even if they are provided one by one, an effect specific to the function can be exhibited.
In the above-described embodiment, a mixer system in which three digital mixers are connected has been described. However, the number of digital mixers to be connected is not limited to this. Further, there may be a plurality of digital mixers constituting the mixer system having an operation panel. For example, a digital mixer used for the operation of the mixer system is provided with an operation panel having a large size and a large number of operation elements, and other digital mixers are provided with a scene recall operation element used for independent operation. It is conceivable to provide a simple operation panel provided with a small number of increase / decrease controls for parameter setting.

In addition to a single digital mixer, an apparatus in which an acoustic signal processing device such as a hard disk recorder, an electronic musical instrument, a karaoke device, a sound source device, a MIDI (Musical Instruments Digital Interface: registered trademark) sequencer or the like has a mixer function. A mixer system as described above may be configured using Further, the connection between the mixer systems may be not a cascade connection but a network connection using Ethernet, IEEE (Institute of Electrical and Electronic Engineers) 1394, USB, or the like.
Further, it is not necessary to edit the layer information using the digital mixer itself, and it is conceivable that the layer information can be edited by a PC (personal computer) or the like and set in the digital mixer.

As is apparent from the above description, according to the mixer system of the present invention, in the mixer system configured by cascading a plurality of digital mixers, the correspondence relationship between the mixing bus and the output channel is variable among the plurality of digital mixers. Even in this case, it is possible to easily maintain the corresponding parameter between the digital mixers at the same value.
Therefore, a highly convenient mixer system can be provided.

It is a block diagram which shows the structure of the mixer system containing the digital mixer which is embodiment of this invention. It is a figure which shows schematic structure of the signal processing which the mixer system shown in FIG. 1 performs. It is a figure which shows the flow of the acoustic signal supplied to the cascade bus shown in FIG. It is a figure which shows the function implement | achieved by a cascade link. It is a figure which shows the structure of the operation panel with which the digital mixer 10 shown in FIG. 1 is provided.

It is a figure which shows the structure of the ch strip in the multipurpose ch strip part shown in FIG. It is a figure which shows the example of a display of the layer setting screen for setting the content of a versatile layer. It is a figure which shows the example of a display of the cascade link setting screen for receiving the setting regarding a cascade link and an output channel link. The example of the data set with the cascade link setting screen shown in FIG. 8 is shown. It is a figure for demonstrating the remote control function in the mixer system shown in FIG.

It is a flowchart of the process which CPU of a digital mixer performs when the content of the current memory 81A shown in FIG. 10 changes. Similarly, it is a flowchart of processing executed by the CPU of the digital mixer when the contents of the current memory 81B ′ or 81C ′ change. 6 is a flowchart of processing executed by the CPU of the digital mixer # 1 shown in FIG. 1 when the device selection switch is operated. Similarly, it is a flowchart of a process when there is an operation of a layer selection switch for selecting an input channel layer. Similarly, it is a flowchart of processing when there is an operation of a fader of the input channel strip unit.

Similarly, it is a flowchart of processing for reflecting a change in fader level of an input channel in signal processing in a DSP. Similarly, it is a flowchart of processing when there is an operation of a layer selection switch for selecting an output channel layer. Similarly, it is a flowchart of processing when there is an operation of a fader of the output channel strip unit. It is a flowchart following FIG. 3 is a flowchart of processing executed by the CPU of the digital mixer # 1 shown in FIG. 1 when a layer selection switch for selecting a multi-use layer is operated. FIG. 21 is a flowchart continued from FIG. 20. 3 is a flowchart of processing executed by the CPU of the digital mixer # 1 shown in FIG. 1 when there is an operation of a fader of a multipurpose ch strip unit. It is a flowchart following FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Mixer system 10, 30 (# 1- # 3) ... Digital mixer, 11 ... CPU, 12 ... Flash memory, 13 ... RAM, 14 ... External apparatus I / O, 15 ... Waveform I / O, 16 ... DSP 17 ... Cascade I / O, 44, 44 '... Mixing bus, 51, 52 ... Cascade bus, 63 ... Output channel, 100 ... Operation panel, 110 ... Input channel strip unit, 111, 121, 131 ... Layer selection switch, 120 ... Output channel strip unit, 130 ... Multi-use channel strip unit, 143 ... Display panel, 144 ... Device selection switch, 160 ... Channel strip, 200 ... Layer setting screen, 300 ... Cascade link setting screen

Claims (4)

A mixer system comprising a plurality of mixing buses, and configured by connecting a plurality of cascaded digital mixers that process and output acoustic signals mixed by the mixing buses in output channels corresponding to the mixing buses,
For each digital mixer,
System setting means for setting a system so that the mixing bus and system have a one-to-one correspondence with any one of the mixing buses provided by itself;
Cascade mix for further mixing the audio signal mixed in each of the mixing buses for which the system is set by the system setting means, and the signal mixed in the mixing bus for which the same system is set in other cascaded digital mixers Means,
A cascade output means for supplying an acoustic signal mixed for each system by the cascade mix means to a mixing bus in which the system is set and the corresponding output channel;
In the mixer system,
Link setting means for setting the presence or absence of a link for each system,
Signal processing in the output channel within the range of the output channel to which the sound signal mixed in the same system is supplied among the output channels provided in each digital mixer for each system in which the link presence is set by the link setting means A mixer system comprising parameter linking means for maintaining parameters that define contents at the same value. A mixer system comprising a plurality of mixing buses, and configured by connecting a plurality of cascaded digital mixers that process and output acoustic signals mixed by the mixing buses in output channels corresponding to the mixing buses,
For each digital mixer,
Association means for associating a plurality of mixing buses and a plurality of cascade-connected systems on a one-to-one basis;
Cascade mix means for further mixing the audio signal mixed in each of the mixing buses associated with the system and the signal mixed in the mixing bus associated with the same system in another cascaded digital mixer When,
A cascade output means for supplying an acoustic signal mixed for each system by the cascade mix means to a mixing bus associated with the system and an output ch corresponding to the system;
In the mixer system,
Link setting means for setting the presence or absence of a link for each system,
Signal processing in the output channel within the range of the output channel to which the sound signal mixed in the same system is supplied among the output channels provided in each digital mixer for each system in which the link presence is set by the link setting means A mixer system comprising parameter linking means for maintaining parameters that define contents at the same value. The mixer system according to claim 1 or 2,
The link can be set collectively for a plurality of systems,
The parameter link means sets the parameter values defining the signal processing content in the output channel to each other within the range of the output channel to which the acoustic signal mixed by any of the plurality of systems to which the collective link is set is supplied. A mixer system comprising means for maintaining the same value. A mixer system according to any one of claims 1 to 3,
In each of the digital mixers, for each of the mixing buses, it is possible to set whether or not to use the acoustic signal mixed in the mixing bus for mixing by the cascade mixing means,
A mixer system characterized in that an acoustic signal mixed by the cascade mixing means is not supplied to an output channel corresponding to a mixing bus that is set not to be used for mixing by the cascade mixing means.

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