JP4462151B2 - Digital mixer - Google Patents

Description

  The present invention relates to a digital mixer that processes acoustic signals supplied from a plurality of acoustic signal input means and outputs them from a plurality of output channels.

Conventionally, digital signals that are output from an output channel after adjusting amplitude characteristics and frequency characteristics in an input channel (ch) and performing signal processing such as mixing by a mixing bus for acoustic signals input from a plurality of signal input units Mixers are known.
Further, in such a digital mixer, the user selects an auxiliary signal that is used auxiliary when setting the signal processing content, such as a test signal generated by an oscillator or a talkback signal input from an operator's microphone or the like. It has been made possible to output to one or more mixing buses. Then, designation of the output destination mixed bus is performed using an on / off button provided corresponding to each output channel on a dedicated screen.
Such a digital mixer is described in Patent Document 1, for example.
“PM5D / PM5D-RH Instruction Manual”, Yamaha Corporation, 2004, p. 96-98, 134-135, 185-187, 207-212

However, in the conventional digital mixer as described above, when a user tries to output an auxiliary signal to a favorite mixing bus, a dedicated screen is opened once and selection / non-selection of each mixing bus is set on the screen. After the operation, the troublesome operation of enabling the output of the auxiliary signal by the switch for enabling the output of the auxiliary signal is necessary. Furthermore, since there are various screens to be displayed on the digital mixer, it is necessary to perform a number of operations only by selecting and displaying the dedicated screen.
Therefore, there is a problem that the operability when outputting the auxiliary signal is poor.
An object of the present invention is to solve such a problem and improve the operability when outputting an auxiliary signal to one or a plurality of mixing buses selected by a user in a digital mixer.

In order to achieve the above object, a digital mixer according to the present invention mixes a plurality of input channels for controlling characteristics of acoustic signals supplied from a plurality of acoustic signal input means and an acoustic signal supplied from the input channels. a plurality of mixing buses, and a plurality of output channels corresponding to the respective mixing buses, and selecting means for selecting one or more of the above mixing buses of the plurality of mixing buses as the output destination of the auxiliary signal, by its means a supply means for supplying the auxiliary signal to set the mixing buses, the digital mixer and an operation panel, a plurality of first operators corresponding to the respective mixing buses, of the plurality of mixing buses 1 or a second operator which a plurality of mixing buses associated provided on the operation panel, in response to the operation of the second operating member, the association to the second operator The first operating element while the output destination control means for the mixing bus to be selected mixing bus that is as the output destination of the auxiliary signal in the selecting means, the second operating element is operated Is provided with an assignment control means for toggling or releasing the mixed bus corresponding to the operated first operator with the second operator .

In such a digital mixer, there is provided switching means for switching validity / invalidity of supply of the auxiliary signal to the mixing bus by the supply means, and the output destination setting means has a series of operations of the second operator. It is preferable to provide means for enabling the supply of the auxiliary signal to the mixing bus according to the first operation, and inverting the validity / invalidity of the supply of the auxiliary signal to the mixing bus according to the subsequent operation. .
Alternatively, the output destination setting means enables the supply of the auxiliary signal to the mixing bus in response to an ON operation of the second operator, and the auxiliary signal in response to an OFF operation of the second operator. There may be provided means for invalidating the supply to the mixing bath.

  According to the acoustic signal processing device of the present invention as described above, it is possible to improve the operability when outputting the auxiliary signal to one or a plurality of mixing buses selected by the user.

Hereinafter, the best mode for carrying out the present invention will be specifically described with reference to the drawings.
First, the configuration of 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 digital mixer.
As shown in FIG. 1, the digital mixer 10 includes a CPU 11, a flash memory 12, a RAM 13, a display 14, a controller 15, an external device input / output unit (I / O) 16, a waveform I / O 17, a signal processing unit ( DSP) 18, which are connected by a system bus 19. And it has a function which performs various signal processing with respect to the acoustic signal inputted from a plurality of input channels (ch), and outputs it from a plurality of output channels.

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, communication in the external device I / O 16 and the waveform I / O 17 is performed. Processing such as controlling the display on the display 14, detecting the operation of the operation element 15, and setting / changing parameter values and controlling the operation of each unit according to the operation is 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 display unit 14 is a display unit that displays various information such as a GUI (graphical user interface) and parameter values in accordance with control by the CPU 11, and includes, for example, a liquid crystal display (LCD), a light emitting diode (LED), or the like. can do. It is also possible to arrange the LED on the back side of the operation element or to laminate the touch panel on the LCD so that the display unit 14 and the operation element 15 are combined.

  The operation element 15 is for receiving an operation on the digital mixer 10 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 14, or a driving means may be provided on the operation element so that it can be moved to an arbitrary position under the control of the CPU 11.

The external device I / O 16 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 17 is an interface for receiving an input of an acoustic signal to be processed by the DSP 18 and outputting the processed acoustic signal. This waveform I / O 17 includes an A / D conversion board capable of analog input of 4 channels (ch) with one board, a D / A conversion board capable of analog output of 4 channels with one board, and 8 channels with one board. A plurality of digital input / output boards capable of digital input / output can be combined as appropriate, and a plurality of boards can be mounted. In practice, signals are input / output through these boards. The waveform I / O 17 is also provided with a talkback input terminal for connecting a talkback microphone or the like for inputting a talkback signal.

  The DSP 18 includes a signal processing circuit, and performs various signal processing such as mixing and equalizing on the acoustic signal input from the waveform I / O 17 according to the values of various parameters included in the operation data stored in the current memory. Signal processing means for outputting to the waveform I / O 17. It is conceivable that the storage area of the current memory is prepared in a memory provided in the RAM 13 or the DSP 18 itself.

Next, FIG. 2 shows the configuration of the DSP 18 shown in FIG. 1 in more detail.
As shown in this figure, the DSP 18 has an input patch 41, an input channel 42, a MIX (mixed) bus 43, a MIX output channel 44, an output patch 45, an oscillator (OSC) 46, and a talkback channel 47.
In the DSP 18, either the analog input port 31 or the digital input port 32 provided in the waveform I / O 17 is patched (connected) to the 24 input channels 42, and the patched ports are connected to each input channel. After the input signal is subjected to signal processing by an attenuator, equalizer, compressor, etc., the processed signal is further level-controlled and transmitted to each of the 12 MIX buses 43.

  The MIX bus 43 of each system mixes the signals input from the input channels 42 and outputs the mixed signals to a 12-channel MIX output channel 44 provided corresponding to each system. In each MIX output channel 44, the signal input from the corresponding bus is subjected to signal processing by an equalizer, a compressor, etc., and further subjected to level control, and the processed signal is converted into a waveform I / O 17 by the output patch 45. Patch the analog output port 33 and the digital output port 34 provided, and output from the output port of the patch destination.

The OSC 46 is a supply unit that includes an oscillator that outputs a sine wave, pink noise, burst noise, or the like as a test acoustic signal, and supplies the signal to the MIX bus 43 of the system selected by the user.
The talkback ch 47 is supply means for supplying a talkback signal input from the talkback input port 35 corresponding to the above-described talkback input terminal to the MIX bus 43 of the system selected by the user.
The contents of signal processing performed by these units provided in the DSP 18 can be controlled by setting predetermined parameter values included in the operation data in the current memory, and the functions of the units are realized by software. Alternatively, it may be realized by hardware.

The OSC 46 is used when checking the operation of devices connected to the digital mixer 10 and checking the characteristics of the venue where the devices are arranged. The talkback signal is used when the operator of the digital mixer 10 wants to convey an instruction by voice to a person on the stage where the speaker connected to the digital mixer 10 is arranged.
The signal input to the MIX bus 43 from the OSC 46 and the talkback ch 47 is a signal mainly used in preparation before the actual production, and is not output to the audience in the venue. Auxiliary signal in the sense that it is input to the input channel 42, mixed by adjusting the acoustic characteristics in the digital mixer 10, and distinguished from the acoustic signal that is actually output to the venue, and used auxiliary when setting the signal processing content. It can be said that. Since it is an auxiliary signal, it is basically unnecessary to adjust the acoustic characteristics other than the level. However, regarding the setting of the output destination, quick change according to the situation of the place is required.
Although a part of the input channel 42 may be used as a talkback channel, even in this case, it can be said that a signal input from the input channel to the MIX bus 43 is an auxiliary signal. Of course, the auxiliary signal is not limited to the talkback signal and the test signal.

Next, FIG. 3 shows a schematic configuration of an operation panel in the digital mixer 10.
The digital mixer 10 has an operation panel 100 configured as shown in FIG. 3. On this operation panel 100, a display panel 101, a user corresponding to the display unit 14 and the operation element 15 shown in FIG. A definition key 102, a layer selection key 103, a cursor key 104, an increase / decrease key 105, a rotary encoder 106, an enter key 107, an OSC key 112, a talkback key 113, a talkback level setting knob 114, a ch strip 120, and the like are provided. A talkback terminal 111 is also provided.

Among these, the display panel 101 is an LCD display for displaying a screen such as a GUI, and is selected by the user from a plurality of screens including a plurality of parameter setting screens for setting various parameters. Screen is displayed.
The user-defined key 102 is a key that can be used as a key for a selected function by assigning a function selected from options prepared in advance. Here, 12 keys of 3 × 3 are provided. As options, for example, it is possible to prepare a button corresponding to a button on the GUI to be displayed on the display panel 101, but it may be related to a function not prepared on the GUI.

  The layer selection key 103 is a key for selecting a layer that defines a channel corresponding to each channel strip 120. When the “output 1” key is pressed, the 12 MIX output channels 44 are selected. When the “input 1” key is pressed, the 1st to 12th input channels 42 are selected, and the “input 2” key is selected. When pressed, the thirteenth to twenty-fourth input channels 42 are respectively associated with the channel strips 120, and the operators included in the channel strip 120 can be used as operators for controlling the parameters of these channels. To do.

The cursor key 104 is a key for instructing the cursor and pointer to move up and down and left and right on the GUI displayed on the display panel 101.
An increase / decrease key 105 and a rotary encoder 106 are operating elements for instructing increase / decrease of a parameter value on the GUI displayed on the display panel 101.
The enter key 107 is a key for instructing selection of an item on the GUI, confirmation of an input value, and the like.

The talkback terminal 111 is an input terminal for a talkback signal. By connecting a microphone or the like to the talkback terminal 111, the voice of the operator of the digital mixer 10 is input as an acoustic signal to the talkback ch 47 via the talkback input port 35. can do.
The OSC key 112 is a key for instructing output of a test signal from the OSC 46.
The talkback key 113 is a key for instructing supply of a signal input to the talkback terminal 111 to the talkback ch 47.
The talkback level setting knob 114 is an operator for setting the level of the talkback signal. This level adjustment may be performed by the talkback ch 47, for example.

  The channel strips 120 are a group of operators for operating signal processing parameter values in the corresponding channels, and 12 channel strips 120 are provided on the operation panel 100. Which channel each channel strip 120 corresponds to is determined by the layer selected by the layer selection key 103 as described above.

Each channel strip 120 includes a rotary encoder 121, a SEL key 122, an ON key 123, a fader 124, and a CUE key 125.
Among these, the rotary encoder 121 is an operator that can be used as an operator for assigning an arbitrary parameter of the corresponding channel and setting the value of the parameter in the corresponding channel.
The SEL key 122 selects the corresponding channel as the selected channel, and when the parameter setting screen is displayed on the display panel 101, the setting target on the screen is the selected channel (or a plurality of channels including the channel). It is a key for changing to a parameter. Here, as will be described later, it can also be used to set the output destination of the test signal and talkback signal.

The ON key 123 is a key for operating on / off of the corresponding channel.
The fader 124 is an operator for operating the volume of the corresponding channel.
The CUE key 125 is a key for operating on / off of the output from the corresponding channel to a CUE bus (not shown) for monitoring. Here, when the CUE key 125 of any channel is on, the CUE control unit 53 performs the above-described control “when CUE is set to on”.

In the digital mixer 10 as described above, a characteristic point is a function for receiving selection of an output destination of a test signal and a talkback signal which are auxiliary signals. Therefore, this point will be described next. Note that the contents of the test signal and the talkback signal are almost the same, so the case of the talkback signal will be described as an example.
In the digital mixer 10, the output destination of the auxiliary signal can be selected by both the GUI displayed on the display panel 101 and the operation element provided on the operation panel 100.

Among these, first, FIG. 4 shows an example of a talkback setting screen which is a GUI displayed on the display panel 101.
As shown in this figure, the talkback setting screen 200 has an input setting unit 210 and a bus allocation unit 220.
The input setting unit 210 includes an input level setting unit 211, a talkback button 212, and a latch setting button 213.

Among these, the input level setting unit 211 is an operation unit for setting the level of the talkback signal, and the parameters set here are the same as the parameters set by the talkback level setting knob 114.
Like the talkback key 113 on the operation panel 100, the talkback button 212 is a button for instructing the supply of a signal input to the talkback terminal 111 to the talkback ch 47. However, the operation of the talkback button 212 is always in the latch mode.
The latch setting button 213 is a button for switching between the latch mode and the non-latch mode of the talkback key 113.

In the latch mode, the supply of the talkback signal to the talkback ch 47 is turned on (validated) in response to the first operation in a series of operations of the talkback key 113 that is not in the on state, and the subsequent operation is performed. This is a mode in which the on / off (valid / invalid) of the supply is reversed accordingly. In the non-latching mode, the supply of the talkback signal to the talkback ch 47 is turned on when the talkback key 113 is turned on (when the talkback key 113 is pressed), and is supplied when the talkback key 113 is turned off (when released). This mode is turned off (invalidated).
That is, in the latch mode, the talkback signal can be turned on / off each time the talkback key 113 is pressed. In the non-latching mode, the talkback signal is turned on only while the talkback key is pressed. Can be.

In addition, the bus assignment unit 220 is provided with 12 MIX bus designation buttons 221 corresponding to the MIX buses 43, and by using these, the designation / cancellation as the output destination of the talkback signal is toggled. The bus to which the talkback signal is output can be set. When performing this setting, the CPU 11 functions as a setting unit.
Since the MIX bus 43 and the MIX output channel 44 have a one-to-one correspondence, the data used for assignment or setting can be easily replaced with data indicating the other, regardless of which data is used. Functions can be realized.

The operation accepted on the talkback setting screen 200 as described above can be immediately reflected in the parameter value stored in the RAM 13 of the digital mixer 10, and the talkback ch 47 can be controlled in accordance with the contents.
However, since there are various screens to be displayed on the display panel 101, the talkback setting screen 200 must be arranged in a deep hierarchy, and several operations are required to call this screen. . Therefore, it is troublesome to call the talkback setting screen 200 one by one when frequently changing the setting of the output destination of the talkback signal.

On the other hand, when using an operator provided on the operation panel 100, the talkback signal ON / OFF can be set by the talkback key 113, but the bus (or output channel) to which the talkback signal is output is set. In this case, this function can be assigned to the user-defined key 102.
In this case, more specifically, a set of one or a plurality of MIX buses 43 stored in correspondence with an arbitrary key of the user-defined keys 102 is set as an output destination of the talkback signal. A function for accepting instructions is assigned and functions as an “assignment key”. This assignment key is the second operator.

  Also, by depressing the SEL key 122 of the ch strip 120 while depressing the allocation key, the MIX bus 43 corresponding to the ch strip 120 is set / released as the output destination of the talkback signal and allocated. The key can be assigned / released by toggle. Further, when the assignment key is pressed, the MIX bus 43 corresponding to the channel strip 120 to which the SEL key 122 belongs becomes the output destination of the talkback signal by turning on / off the lamp 122a of each SEL key 122. Whether or not it is displayed. The SEL key 122 is a first operator.

  Here, the ch strip 120 directly corresponds to the channel assigned by the layer. However, when the MIX output ch 44 is assigned to the ch strip 120, the ch strip 120 corresponds to the MIX output ch 44 and 1. It is considered that the MIX bus 43 corresponding to one-to-one is also supported.

  The contents of the assignment changed by the operation of the SEL key 122 are stored in correspondence with the pressed assignment key, and used for the talkback signal output setting performed when the same assigned key is pressed next time. Like that. This storage can be performed, for example, by preparing an assignment list corresponding to the assignment key and registering the assigned MIX bus 43 number in the list.

FIG. 5 shows an example of the list.
The bus to which the talkback signal is output is a setting that is temporarily required on the spot and there is no versatility to store it, so it is stored as a part of the scene in the scene memory etc. This is because the setting is not suitable for preparing or storing a dedicated library.

It is also possible to function a plurality of user-defined keys as assignment keys, prepare an assignment list corresponding to each key, and register different combinations of buses in correspondence.
In addition, as the function of the assignment key, there are both a case where it is desired to set only the output destination of the talkback signal as described above and a case where it is desired to operate the talkback signal on / off simultaneously. Therefore, in order to meet the latter demand, the digital mixer 10 can set the “link” so that the talkback key 113 is also operated at the same time when the assignment key is operated, and is displayed on the display panel 101. The link can be switched on / off by a GUI (not shown). It is also possible to assign a function for switching link on / off to any of the user-defined keys 102.

Here, processing for realizing the function of the assignment key as described above will be described with reference to the flowcharts of FIGS.
First, FIG. 6 shows a flowchart of processing in the non-latching mode when an on event of an assigned key (user-defined key 102 to which the function is assigned) is detected.
When the CPU 11 detects an on-event indicating that the assignment key has been pressed, the CPU 11 starts the processing shown in FIG. 6 when the operation of the talkback key 113 is set to the non-latching mode.
If the value of the on flag indicating whether any one of the assignment keys is pressed is 1 (S11), the other on-key has already been pressed, so the current on-event is ignored. The process is terminated as it is.

  On the other hand, if the on flag is not 1 (if it is 0), the on flag is set to 1 (S12), and information on the operated assignment key is stored (S13), and according to the assignment list corresponding to the assignment key, The bus registered in the list is set as the output destination of the talkback signal (S14). This setting is the same as the setting performed by the bus assignment unit 220 in FIG. 4. If the talkback setting screen 200 is being displayed on the display panel 101, the display is also updated.

  Thereafter, the lighting / extinguishing of the lamp 122a of the SEL key 122 of each channel strip 120 is changed according to the contents of the assignment list corresponding to the selected layer and the operated assignment key, and which bus is assigned to the operated assignment key. The display indicating whether the channel is assigned is performed by turning on the lamp 122a of the SEL key 122 of the channel strip 120 corresponding to those channels (S15). Here, lighting / extinguishing may be controlled in accordance with the setting contents of the output destination of the talkback signal, and the display indicating the output destination may be performed.

If the link setting is on (S16), the output of the talkback signal is set to on (S17) as the same process as when the on event of the talkback key 113 on the operation panel 100 is detected. The display 14 displays that the talkback is in progress (S18), and the process is terminated. On the other hand, if it is OFF in step S16, the process is terminated as it is.
In the above processing, the CPU 11 functions as an output destination control unit. In step S14, it also functions as a setting unit, and in step S17, it also functions as a switching unit.

Next, FIG. 7 shows a flowchart of processing in the non-latching mode when an off event of the assigned key is detected.
When the CPU 11 detects an off event indicating that the assigned key has been released, the CPU 11 starts the processing shown in FIG. 7 when the operation of the talkback key 113 is set to the non-latching mode.
If the off event is not the assigned key stored in step S13 of FIG. 6 (S21), the off event detected this time is an off event corresponding to the on event ignored in the process of FIG. It is determined that the off event is ignored and the process is terminated.

On the other hand, if “YES” in the step S21, the on flag is set to 0 (S22) as processing corresponding to the off event, and the lighting / extinguishing of the lamp 122a of the SEL key 122 of each ch strip 120 is selected. Changes are made according to the contents of the layer and SEL parameters, and the display returns to the normal display in which the assignment key is not pressed (S23).
Here, the SEL parameter is a parameter indicating a channel that is currently selected as a selected channel by operating the SEL key 122. If the currently selected layer includes the selected channel, the SEL parameter corresponds to the selected channel. The lamp 122a of the SEL key 122 of the ch strip 120 is turned on, and all the lamps 122a of the other SEL keys 122 are turned off.

If the link setting is on (S24), the talkback signal output is set to off (S25) as the same process as when the off event of the talkback key 113 on the operation panel 100 is detected. The display indicating that the talkback is in progress is stopped (S26), and the process is terminated. On the other hand, if it is OFF in step S24, the process is terminated as it is.
Also in the above processing, the CPU 11 functions as an output destination control unit, and also functions as a switching unit in step S25.

Next, FIG. 8 shows a flowchart of the process in the latch mode when an on event of the assigned key is detected.
In the latch mode, ON / OFF of the talkback signal is inverted every time the assignment button is pressed, so that the display content of the lamp 122a that changes depending on whether the assignment button is pressed or released. Does not necessarily correspond.

When the CPU 11 detects an on event indicating that the assignment key has been pressed, if the operation of the talkback key 113 is set to the latch mode, the CPU 11 starts the process shown in FIG.
If the value of the on flag indicating whether or not any assignment key is pressed is 1 (S31), the other on-key has already been pressed, so the current on-event is ignored. The process is terminated as it is.

On the other hand, if the on flag is not 1 (if it is 0), the on flag is set to 1 (S32), and information on the operated assignment key is stored (S33).
Thereafter, it is determined whether or not the content of the allocation list corresponding to the operated allocation switch matches the setting content of the output destination of the talkback signal (S34). If there is a match, since it is considered that neither the contents of the assignment list nor the output destination of the talkback signal have been changed since the previous assignment switch operation, this operation is a series of operations following the previous operation. It can be judged. Also, if they do not match, it is thought that the contents of the allocation list or the output destination of the talkback signal have changed since the previous allocation switch operation, or an allocation switch different from the previous one was operated, so this operation is It can be determined that this is not the series of operations following the previous operation, but the first operation among the series of operations of the assignment switch.

  If they do not match in step S34, the process proceeds to step S35 and subsequent steps, and the talkback signal output destination is set and the lamp 122a is turned on / off in the same manner as in steps S14 and S15 of FIG. S35, S36). After that, if the link setting is on (S37), the output of the talkback signal is set to on as the same process as when the on event related to the first operation of the talkback key 113 on the operation panel 100 is detected. Along with (S38), a display indicating that talkback is in progress is performed (S39), and the process is terminated. On the other hand, if it is OFF in step S37, the process is terminated as it is.

If they match in step S34, the process proceeds to step S40 and the subsequent steps, and lighting / extinguishing control of the lamp 122a is performed (S40), but setting of the output destination of the talkback signal is not necessary. After that, if the link setting is on (S41), the output on / off of the talkback signal is reversed as the same process as when the on event related to the second and subsequent operations of the talkback key 113 is detected ( At the same time, the display indicating that the talkback is in progress is updated accordingly (S43), and the process is terminated. On the other hand, if it is OFF in step S41, the processing is terminated as it is.
Also in the above processing, the CPU 11 functions as an output destination control unit. Further, it also functions as a setting unit in step S35 and also as a switching unit in steps S38 and S42.

Next, FIG. 9 shows a flowchart of processing in the latch mode when an off event of the assigned key is detected.
When the CPU 11 detects an off event indicating that the assigned key is released, the CPU 11 starts the process shown in FIG. 9 when the operation of the talkback key 113 is set to the latch mode.
If the off event is not the assigned key stored in step S33 of FIG. 8 (S51), the off event detected this time is an off event corresponding to the on event ignored in the process of FIG. It is determined that the off event is ignored and the process is terminated.

On the other hand, if “YES” in the step S51, the on flag is set to 0 (S52) as processing corresponding to the off event, and the lighting / extinguishing of the lamp 122a of the SEL key 122 of each ch strip 120 is selected. It changes according to the contents of the layer and the SEL parameter, returns to the normal display in a state where the assignment key is not pressed (S53), and the process is terminated.
In the latch mode, there is no particular operation in response to the off event of the talkback key 113, so there is no need to make a determination regarding link setting.

Next, FIG. 10 shows a flowchart of processing when an ON event of the SEL key is detected. This process is common to the latch mode and the non-latch mode.
When the CPU 11 detects an on event indicating that the SEL key 122 is pressed, the CPU 11 starts the process shown in FIG. Then, the channel for which the SEL key is operated, that is, the channel information corresponding to the operated SEL key is acquired from the channel strip to which the SEL key having an on-event belongs and the information of the set layer (S61). ).

If the ON flag is not 1 (S62), the SEL key is not operated at the same time as the assignment key. Therefore, the process related to the normal function of the SEL key is performed (S69), and the process is terminated.
On the other hand, if the ON flag is 1, the process proceeds to step S63 and subsequent steps in the case of simultaneous operation with the assigned key. However, if the channel for which the SEL key has been operated is not the MIX output channel 44 (S63), the bus corresponding to that channel will not be the output destination of the talkback signal, that is, registered in the assignment list. Therefore, the process is terminated as it is.

  If the channel is the MIX output channel 44 in step S63, if the bus corresponding to the channel for which the SEL key has been operated is already registered in the allocation list (S64), the bus is deleted from the allocation list and allocated. Is canceled, and the corresponding update is performed for the setting of the output destination of the talkback signal (S65). Corresponding to this, the lamp of the SEL key having an on-event is turned off, indicating that the assignment to the assignment key of the corresponding bus is released (S66), and the process is ended.

  On the other hand, if it is not registered in the assignment list in step S64, the bus is added to the assignment list for assignment, and the corresponding setting for the output destination of the talkback signal is also made (S67). In response to this, the lamp of the SEL key having an on-event is turned on to indicate that the assignment to the assignment key of the corresponding bus has been performed (S68), and the process ends.

Note that the assignment list used in steps S64, S65, and S67 is an assignment list corresponding to the assignment key (assignment key being operated) stored in step S13 in FIG. 6 or step S33 in FIG. Further, in steps S65 and S67, only the setting change of the output destination of the talkback signal is performed, and thereafter, the change of the output destination is reflected in the allocation list with or before the detection of the off event of the allocation key as a trigger. You may do it.
In the above processing, the CPU 11 functions as an allocation control unit.

Up to this point, the talkback signal output destination setting and the talkback signal on / off switching have been described. However, the test signal output destination setting and the test signal on / off switching should be performed in the same manner. Can do.
This is the same whether the GUI is used or the operator on the operation panel 100 is used. However, it is preferable that the function relating to the talkback setting and the function relating to the test signal setting are prepared separately so that they are assigned to different user-defined keys, and the assignment table is also prepared separately. It is preferable that the link and the latch can be set independently. However, since the test signal is considered to be normally used in the non-latching mode, it may be fixed here.

In the digital mixer 10, the above-described assignment key function can be realized by the CPU 11 performing the above processing.
Then, by setting the MIX bus 43 of the set that has been stored in correspondence with the key just by pressing the assigned key once, it is set as an output destination of auxiliary signals such as a talkback signal and a test signal. In addition, by pressing the SEL key 122 after that, the MIX bus 43 as the output destination of the auxiliary signal can be arbitrarily selected, or the contents can be stored so that it can be used when the assigned key is pressed next time. can do. Therefore, extremely high operability can be obtained when an auxiliary signal is output to one or a plurality of mixing buses designated by the user. Furthermore, since the operator to be used can be directly operated by the user on the operation panel 100, it is not necessary to perform an operation such as calling a menu in a deep hierarchy, and high operability can also be obtained in this respect.

Further, since the output destination of the auxiliary signal is selected by the operation element provided on the ch strip 120, the correspondence between the operation element and the bus is easy to understand. In addition, since the functions of the controls having other functions are switched temporarily when the assigned key is pressed, there is no need to provide a dedicated control for selecting the bus, and the panel area can be reduced. Contributes to cost reduction. In this sense, the same effect can be obtained by using other operation elements in the ch strip such as the ON key 123 and the CUE key 125 other than the SEL key 122. Further, since it is possible to display the presence / absence of assignment, it is more preferable.
If a plurality of assignment buttons are provided and the MIX output buses 43 can be assigned to the respective assignment buttons, the bus to which the auxiliary signal is output is set between the plurality of sets of MIX output buses 43 by operating each assignment button. Can be switched instantly.
The talkback signal output destination and the test signal output destination can be made common so that they can be set using a common assignment key or assignment list. Such a function can also be prepared.

This is the end of the description of this embodiment, but it goes without saying that the configuration of the apparatus, specific processing contents, screen display contents, and the like are not limited to those described in the above-described embodiment.
For example, in the above-described embodiment, an example in which “first-come-first-served” control is performed to give priority to a previously operated key when a plurality of assigned keys are operated simultaneously is not limited to this. .
As a reverse method, the “last arrival priority” method that prioritizes keys that are operated later is adopted, and each time the assigned key is pressed, the output destination of the auxiliary signal according to the assigned list corresponding to the pressed key The assignment list may be updated according to the pressing of the SEL key only for the list corresponding to the assignment key that was pressed last.

It is also conceivable to update the allocation list in response to the pressing of the SEL key for the list corresponding to each of the pressed allocation keys.
Further, when the assignment key currently used for setting the output destination of the auxiliary signal is released from the state where a plurality of assignment keys are pressed, the remaining assignment keys that are being pressed are set to 1 on some basis. It is also conceivable to select one key and set the output destination of the auxiliary signal according to the assignment list corresponding to the assigned key.

  As another point, in the above-described embodiment, the mixed bus is merely 12 MIX buses 43. However, the present invention is also applicable to a case where there are different buses such as a stereo bus and a matrix bus. Is applicable. In this case as well, the first operator corresponding to the bus is necessary, but a layer for allocating these buses to the ch slots may be prepared, or a dedicated operator may be prepared.

  In the above-described embodiment, the example in which the OSC key 112 and the talkback key 113 are provided on the operation panel 100 has been described. However, these keys may not be provided, and the user-defined keys 102 may be provided as necessary. It can be made to function as a key. This is because if the link described above is used, the talkback signal and the test signal can be switched on / off without using these keys.

Further, the output destination of the auxiliary signal is not limited to the mixed bus, and other positions may be output destinations. For example, the auxiliary signal may be added to the signal of the input channel or the output channel, and the input channel or the output channel may be set as the output destination of the auxiliary signal or registered in the assignment list.
In addition, the operators used for applications such as the above-described assignment keys and SEL keys may be operators that accept operations by other methods such as rotation, slide, and touch on the screen, instead of pressing operations. Furthermore, it is possible to provide these as dedicated operators for setting the output destination of the auxiliary signal.

In addition to a single digital mixer, the present invention can also be applied to a device in which an acoustic signal processing device such as a hard disk recorder, electronic musical instrument, karaoke device, sound source device, MIDI sequencer, etc. has a mixer function. Of course. Of course, the present invention can also be applied to a case where a suitable software is executed on a PC to function as a mixer.
Further, the present invention can be applied to the case where the operation panel 100 provided with the user-defined key 102 and the channel strip 120 described above is provided not as the same housing as the main body of the digital mixer 10 but as an external physical controller. Even in this case, the processing performed by the CPU of the digital mixer in response to the operation of the operator may be the same as that described above.

As is clear from the above description, according to the digital mixer of the present invention, the operability when outputting the auxiliary signal to one or a plurality of mixing buses selected by the user can be improved.
Therefore, a digital mixer with high operability can be provided.

It is a block diagram which shows the structure of the digital mixer which is embodiment of this invention. It is a figure which shows the structure of DSP shown in FIG. 1 in detail. It is a figure which shows schematic structure of the operation panel in the digital mixer shown in FIG. It is a figure which shows the example of a talkback setting screen. It is a figure which shows the example of an allocation list | wrist.

3 is a flowchart of processing in a non-latch mode that is executed when the CPU of the digital mixer shown in FIG. 1 detects an on event of an assigned key. Similarly, it is a flowchart of processing in a non-latch mode when detecting an off event of an assigned key. Similarly, it is a flowchart of processing in a latch mode when an on event of an assigned key is detected. Similarly, it is a flowchart of processing in a latch mode when an off event of an assigned key is detected. Similarly, it is a flowchart of processing when an ON event of a SEL key is detected.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Digital mixer, 14 ... Display, 15 ... Controller, 17 ... Waveform I / O, 18 ... DSP, 19 ... System bus, 35 ... Talkback input port, 42 ... Input channel, 43 ... MIX bus, 44 ... MIX output channel, 46 ... OSC, 47 ... Talkback channel, 100 ... Operation panel, 101 ... Display panel, 102 ... User defined key, 111 ... Talkback terminal, 112 ... OSC key, 113 ... Talkback key, 114 ... Talk Back level setting knob, 120 ... ch strip, 122 ... SEL key, 122a ... lamp, 200 ... Talkback setting screen, 210 ... Input setting unit, 211 ... Input level setting unit, 212 ... Talkback button, 213 ... Latch setting button , 220 ... bus allocation part, 221 ... MIX bus designation button

Claims (3)

A plurality of input channels for controlling the characteristics of the acoustic signals supplied from the plurality of acoustic signal input means;
A plurality of mixing buses for mixing the acoustic signals supplied from the input channels;
A plurality of output channels corresponding to each of the mixed buses;
Selecting means for selecting one or more of the mixing buses of said plurality of mixing buses as the output destination of the auxiliary signal,
Supply means for supplying the auxiliary signal to the mixing bus set by the means;
A digital mixer having an operation panel,
A plurality of first operators corresponding to each of the mixed buses, and a second operator associated with one or more of the plurality of mixed buses on the operation panel;
Wherein in response to operation of the second operation member, said second output destination control means for the mixing buses that are correlated to the operator and mixing bus is selected as the output destination of the auxiliary signal by the selection means When,
When the first operating element is operated while the second operating element is operated, the response to the second operating element of the mixed bus corresponding to the operated first operating element with or digital mixer, characterized in that the release is provided and assignment control means for performing a toggle. The digital mixer according to claim 1,
Switching means for switching between valid / invalid supply of the auxiliary signal to the mixing bus by the supply means;
The output destination control means enables the supply of the auxiliary signal to the mixing bus in accordance with the first operation in a series of operations of the second operator, and the auxiliary signal in response to the subsequent operation. A digital mixer comprising means for inverting the validity / invalidity of the supply to the mixing bus. The digital mixer according to claim 1,
Switching means for switching between valid / invalid supply of the auxiliary signal to the mixing bus by the supply means;
In the output destination control means, the supply of the auxiliary signal to the mixing bus is enabled according to the ON operation of the second operation element, and the auxiliary signal is output according to the OFF operation of the second operation element. A digital mixer comprising means for invalidating the supply to the mixing bus.

Images