JP4023410B2 - Mixing equipment - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to a mixing apparatus that can directly output from an input channel to an output port.
[0002]
[Prior art]
Conventionally, the level and frequency characteristics of signals output from a large number of microphones or electrical / electronic musical instruments are adjusted, mixed and sent to a power amplifier or various recording devices, mixed into several mixing groups, and effects or performances. There is known a mixing device for sending out to a player. The operator who operates the mixing device adjusts the volume and tone of each instrument sound and singing audio signal to the state that seems to best represent the performance by operating various panel controls on the mixing console. is doing. The mixing apparatus includes a plurality of input channels as input signal sequences, a bus for mixing signals output from the input channels, and an output channel that is an output sequence for outputting the mixed signals. Each input channel controls the frequency characteristics and mixing level of the input signal and outputs it to each mixing bus, and each mixing bus mixes the input signal and outputs it to the corresponding output channel. Each output channel controls and outputs the level of a signal input from the mixing bus.
[0003]
[Problems to be solved by the invention]
There is a digital mixer having an output patch that can arbitrarily set to which of the output ports the output from the output channel that outputs the mixing output is a digital mixer that uses the signal to be handled as a digital signal. . In such a digital mixer, the output signal from each input channel is selectively supplied to the mixing bus. In each mixing bus, the signal supplied from the input channel is mixed, and the mixed signal corresponds to the bus. Are supplied to output channels provided. Each output channel supplies its output signal to an output patch, and the output patch is connected to multiple output channels and multiple input channels as signal input sources, and as signal output destinations. Multiple output ports are connected. In this output patch, for each output port, any one of a plurality of output channels and a plurality of input channels can be connected as a supply source of a signal output to the output port.
[0004]
In the output patch, for each output port, one of a plurality of output channels or a plurality of input channels can be set as a signal supply source to the output port. In this case, there may be an output port that does not set an output channel or an input channel. When such setting is performed, in the output patch, connection according to the setting is performed for each output port. That is, according to the output channel setting that sets the output channel as the input source of the output port or the direct output setting that sets the input channel as the input source of the output port, the connection between the output channel or the input channel and the output port is performed. Is called. The direct output that can set the input channel as the input source of the output port is, for example, when the signal of a certain input channel is output without mixing and recorded on the multitrack recorder as it is, or when the mixing bus is used for other mixing It is used when you want to output the signal of the input channel that is in a fully used state to the outside.
[0005]
By the way, since only one of the output channel and the input channel can be set for each output port, the direct output setting for setting the input channel as the input source to the output port for which the output channel is set When canceling, it is necessary to cancel the setting of the output channel set as the input source in the output port and set the input channel as the input source in the output port. For this reason, there is a problem that direct output cannot be set easily.
Also, in order to be able to use the direct output temporarily, it is better that the direct output can be quickly turned on / off. However, since the setting of direct output becomes very complicated as described above, there is a problem in that the direct output cannot be quickly turned on / off.
[0006]
Accordingly, an object of the present invention is to provide a mixing device that can quickly turn on / off direct output in which an input channel is set as an input source of an output port, and can easily set direct output. It is said.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the mixing device of the present invention sets one output channel of a plurality of output channels as an input source of a signal to the output port for each output port of the plurality of output ports. Output patch setting means, and for each input channel of a plurality of input channels, one of the plurality of output ports is connected to the signal of the input channel. Directly Direct output setting means for setting as an output destination for output, and first switch means for specifying on or off direct output for each input channel of a plurality of input channels; The second switch means for designating on or off the link function for controlling the first switch means in conjunction with the setting of the direct output setting means, and when the link function is designated on for the second switch means, Link means for controlling the first switch means so that the direct output of the input channel is designated to be turned on in response to the direct output setting means being set to an output destination other than the non-selected state by the direct output setting means. It has. The output patch means directly connects each input channel for which direct output is designated ON by the first switch means to the output port designated as the output destination of the input channel by setting of the direct output setting means. In addition, each output port that is not directly connected among the plurality of output ports is patch-connected to an output channel that is set as an input source of the output port by the setting of the output patch setting means. As a result, by operating the first switch means to designate direct output on / off, the direct output can be quickly turned on / off and the direct output can be easily set. .
[0008]
Also, In the mixing device of the present invention, Output destination Output port selected as one output port to another output port changed In this case, it is assumed that the output destination is set to other than the non-selected state in the input channel. The direct output of the input channel can be automatically turned on. Furthermore, In the mixing apparatus of the present invention Output destination in direct output setting means In response to being set to unselected The direct output can be automatically turned off.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram showing the configuration of a digital mixer which is an embodiment of the mixing apparatus of the present invention.
In the digital mixer 1 according to the embodiment of the present invention shown in FIG. 1, a CPU (Central Processing) that controls the overall operation of the digital mixer 1 and generates a control signal according to the operation of a mixing operator. Unit) 10, a rewritable nonvolatile flash memory 11 in which operation software such as a mixing control program executed by the CPU 10 is stored, and a RAM (Random Access Memory) in which the work area of the CPU 10 and various data are stored 12 is provided. Thus, by storing the operation software in the flash memory 11, the operation software can be upgraded by rewriting the operation software in the flash memory 11. Other devices such as a digital recorder are connected to the digital mixer 1 via other I / O 13 which is an input / output interface.
[0010]
The signal processing unit 15 is configured by using a large number of DSPs (Digital Signal Processors), and performs mixing processing, effect processing, and the like under the control of the CPU 10. Further, all inputs and all outputs of the digital mixer 1 are performed by a waveform I / O (waveform data interface) 14. This waveform I / O 14 has 32 analog input ports provided with AD converters for converting analog signals input from the outside into digital signals for input, and 8 digital input ports for inputting digital signals from the outside. It has 16 analog output ports (including 8 omni ports and 4 monitor ports) with DA converters that convert digital signals to analog signals for output. The waveform I / O 14 is further provided with six card slots, and an input port and an output port can be added by installing an expansion card in the card slot. For example, when a 4-port analog input card is attached as an expansion card, 4 analog input ports are added. When a 4-port analog output card is installed, 4 analog output ports are added. When an 8-port digital I / O card is installed, 8 digital input ports and 8 digital output ports are added. When a 16-port digital I / O card is installed, 16 digital input ports and 16 digital output ports are added.
[0011]
The display 16 is a display composed of a liquid crystal display device or the like that displays an output patch setting screen, a direct output setting screen, and the like which will be described later. The electric fader 17 is a fader that adjusts the output level of signals sent to a mixing bus (MIX bus) and AUX bus, which will be described later, and the output level of signals output from those buses, and is adjusted manually and electrically. Can do. The operator 18 includes a display selection switch on the display 16, a routing switch including a mixer bus setting switch and a direct output setting switch for each input channel, a cursor movement key for moving a cursor displayed on the display 16, and a value to be set This is an operation element including a rotary encoder for selecting, an enter key for confirming a set value, and the like.
[0012]
An outline of the appearance of the panel in the digital mixer 1 according to the present invention is shown in FIG.
In FIG. 2, a display selection switch 20 including a large number of switches is provided on the left side of the display 16, and settings for setting various values in the display 16 by operating the display selection switch 20. A screen or a menu screen can be displayed. Further, on the right side of the display 16, a MIX bus setting switch 21a for controlling the output of the input channel selected by the selection switch 17a and a routing switch 21 including a direct output setting switch 21b are provided. The MIX bus setting switch 21a in the routing switch 21 includes switches 1 to 8 and can turn on / off the outputs of eight MIX buses from the selected input channel for each bus. The direct output setting switch 21b is a switch for turning on / off a direct output, which will be described later, set for the selected input channel.
[0013]
Below the display 16, all the input channels are supported, and some of the input channels are assigned to the electric faders 17 that control the level of each channel. An electric fader 17 for controlling the level of the input channel is provided. The electric fader 17 includes a selection switch (SEL) 17a for selecting an input channel controlled by the electric fader 17, a solo switch 17b for setting the input channel to the solo mode, and a channel for turning on / off the input channel. A switch 17c is provided. Further, a cursor movement key 22 for moving the cursor displayed on the display 16 up, down, left and right, a rotary encoder 23 capable of selecting various values to be set, and a setting value selected by the rotary encoder 23 are determined. An enter key 24 is provided. Note that the SW1 to SW4 tab selection switch 26 is a switch for selecting a tab for switching display contents displayed on the display 16.
[0014]
Next, FIG. 3 shows an equivalent functional block diagram in which mixing processing is performed in the digital mixer 1 having the configuration shown in FIG. 1 according to the present invention.
In FIG. 3, an analog signal input to an analog input unit (A input) 40 having a plurality of analog input ports is converted into a digital signal by an internal AD converter and input to an input patch 43. A digital signal input to a digital input unit (D input) 41 having a plurality of digital input ports is input to an input patch 43. Further, the digital mixer 1 is provided with a built-in effector 42 including, for example, eight effectors. A signal to which an effect is given by the built-in effector 42 is also input to the input patch 43. Here, each effector of the built-in effector 42 has a plurality of virtual digital output ports as input portions for a plurality of signals to the effector, and a virtual portion as an output portion for a plurality of signals to which the effect is given by the effect. A plurality of digital input ports.
[0015]
The input patch 43 selectively patches (connects) any one input port of the plurality of input ports that are input sources of signals for each input channel of the plurality of input channel units 44 that are, for example, 96 channels. Each input channel is supplied with a signal from an input port patched by an input patch 43. Each input channel in the input channel unit 44 includes a noise gate, a compressor, a delay, a fader, a level adjustment unit to the MIX bus 45 and the AUX bus 46. In these input channels, the frequency characteristics and the MIX bus 45 are provided. The level output to the AUX bus 46 is controlled. The 96-channel digital signals output from the input channel unit 44 are selectively output to one or a plurality of eight mixing buses (MIX buses) 45 and to one or a plurality of twelve AUX buses 46, respectively. Output selectively. Further, the 96-channel digital signal output from the input channel unit 44 is directly output to the output patch 49.
[0016]
In the MIX bus 45, in each of the eight buses, one or a plurality of digital signals selectively input from any of the 96 input channels are mixed, and a total of 8 MIX outputs are mixed into the MIX output channel. Part (MIX output ch) 47. As a result, an 8-channel MIX output mixed in 8 ways can be obtained. In many cases, the output from the MIX bus 45 is used as the final output. In the AUX bus 46, in each of the 12 buses, one or a plurality of digital signals selectively input from any of the 96 input channels are mixed, and a total of 12 channels of AUX outputs are output as AUX. It is output to the output channel section (AUX output channel) 48. Thereby, 12 channels of AUX output mixed in a maximum of 12 ways can be obtained. The output from the AUX bus 46 is sent to the built-in effector 42 as an intermediate output, for example. The MIX output channel section 47 and the AUX output channel section 48 are configured by 8 or 12 output channels provided with an equalizer, a compressor, a delay, a fader, and the like.
[0017]
The 8-channel MIX output output from the MIX output channel section 47 and the 12-channel AUX output output from the AUX output channel section 48 are supplied to the output patch 49. In the output patch 49, one of the 8 channels of the MIX output channel section 47, the 12 channels of the AUX output channel section, and the 96 channels of the input channel section 44, which are signal input sources, is output to each of the output ports. Each port can be selectively patched (connected), and a signal from a channel patched by the output patch 49 is supplied to each output port. The built-in effector 42 adds reverb, echo and chorus effects to the digital audio signal. The built-in effector 42 is also realized by a DSP constituting the signal processing unit 15. The built-in effector 42 is supplied with a signal from the output patch 49 via the digital output port, and an output obtained by adding an effect to the signal can be returned to the input patch 43 via the digital input port. ing.
[0018]
The digital output signal supplied to the analog output unit (A output) 50 having a plurality of analog output ports is converted by a DA converter incorporated in the analog output unit (A output) 50 having a plurality of analog output ports. Converted to analog output signal. And the analog output signal output from the analog output part (A output) 50 provided with a plurality of analog output ports is amplified and emitted from the speaker. A digital audio signal output from a digital output unit (D input) 51 having a plurality of digital output ports is supplied to a multi-track recorder, DAT or the like so that it can be digitally recorded.
[0019]
Further, in the digital mixer 1, any one or a plurality of (8 + 12) channel output channels in the MIX output channel section 47 and the AUX output channel section 48 can be selectively monitored. The selection of the monitor signal to monitor which output signal is performed by the monitor selector 53, and the selected monitor signal is mixed in the monitor mixer 54. Next, the signal is converted into an analog signal by a monitor analog output unit (monitor A output) 55 and output from a monitor / speaker or a monitor headphone.
[0020]
As described above, in the output patch 49, the output of each channel of the input channel section 44 can be directly patched (connected) to each output port. This patch is called a direct output. This direct output is an input channel in which the signal of an input channel is output without being mixed and recorded on the multitrack recorder as it is, or when the MIX bus 45 and the AUX bus 46 are all used for other mixing. This is used when outputting the above signal to the outside. On the other hand, the other patches in the output patch 49, that is, patches from each channel of the MIX output channel section 47 and the AUX output channel section 48 to each output port are called output patches. That is, in the output patch 49 of the digital mixer 1, two settings are performed: an output patch setting related to the output patch and a direct output setting related to the direct output.
[0021]
When setting the output patch, the display selection switch 20 is operated to display the output patch setting screen shown in FIG. In the output patch setting screen shown in FIG. 7, the tab [SLOT1-2] is selected, and the output patch setting screen is used to set the output patch of the output ports of SLOT1 and SLOT2. SLOT is the six card slots of the waveform I / O 14 described above, and SLOT1 indicates the first slot. Since the expansion card installed in the slot has a maximum of 16 ports, in this output patch setting, the input source can be set for each of the 16 output ports. When an expansion card with a number of output ports smaller than 16 is installed, the setting of the number of output ports is used in ascending order of the output port number, and the settings of the remaining output ports are ignored. That is, as shown in FIG. 7, a cursor frame is provided for enabling the setting of an input source for each output port of each slot. In the example shown in FIG. 7, the output port number “ “1” cursor frame is selected, and only the cursor frame where the cursor is located is displayed with a different display mode, such as thick or blinking, and the input source of output port 1 of SLOT 1 can be set. Has been. By operating the tab selection switch 26 to select the tab [SLOT3-4], tab [SLOT5-6] or tab [OMNI OUT], each of the 16 output ports of SLOT3, 4 and SLOT5, 6 or omni An output patch setting screen for setting output patches for the eight output ports is displayed on the display 16.
[0022]
In the example shown in the figure, the output channel 1 (AUX1) of the AUX output channel section 48 is set as the input source of the output port 1 of SLOT1, but by operating the rotary encoder 23 while the cursor is present here, The input source can be arbitrarily selected or can be non-selected (NONE). However, in the output patch setting, one channel can be selected from all 20 channels of the MIX output channel unit 47 and the AUX output channel unit 48 as an input source. In FIG. 7, “DIRECT1” is set to the output port 9 of SLOT1. That is, it is indicated that the direct output of the input channel set by DIRECT1 is turned on, and the direct output setting has priority over the output patch setting at the output port 9. For this reason, even if the cursor is moved to the cursor frame of the output port 9 and an attempt is made to change the setting of the input source, the change cannot be made here, and the cursor frame is set as an unsettable frame. The cursor on the various setting screens can be moved back and forth and left and right by operating the cursor movement key 22.
[0023]
When setting the direct output, the display selection switch 20 is operated to display the direct output setting screen shown in FIG. The direct output setting screen illustrated in FIG. 8 is a screen for performing direct output setting of 48 input channels of input channel 1 to input channel 48. Then, the tab selection switch 26 is operated to display the tab [D. When OUT49-96] is selected, a direct output setting screen for direct output setting of 48 input channels from the input channel 49 to the input channel 96 is displayed on the display 16. In the direct output setting, an output port for direct output can be set for each input channel. For this reason, as shown in FIG. 8, a cursor frame is set for each of input channel numbers 1 to 48, and only the cursor frame where the cursor is currently located is displayed with a different display mode such as thick or blinking. Yes.
[0024]
In the example shown in FIG. 8, the input channel 1 is selected, and the output port number “S1-01” is selected as the output port of the input channel 1. The output port number “S1-01” indicates the output port 1 of the expansion card attached to SLOT1. For an input channel for which “NONE” is set, the direct output destination is not selected, that is, a non-selected state is indicated. Here, the direct output destination of the input channel selected by the cursor can be arbitrarily selected by operating the rotary encoder 23, or can be made unselected, and can be selected by operating the enter key 24 after selection. The selected output port or non-selected state can be determined. However, in the direct output setting, it is possible to select one port from among the 8 output ports of Omni or an output port added by an expansion card as an output destination. Thus, in the direct output setting, any output port can be set for each input channel.
[0025]
Further, when a direct output setting operation is performed on one input channel, a direct output link switch (DOL switch) 25 that changes the on / off setting of the direct output of the input channel in relation to the operation is provided. , Provided as shown in FIG. For example, when the output port “S1-01” is newly set as the output destination of the input channel 1 in a state where the cursor is placed on the DOL switch 25 and the DOL switch 25 is turned on, the direct output of the input channel 1 is linked to that. Is turned on. In this case, in the output patch 49, the direct output patch from the input channel 1 to the output port S1-01 is performed in preference to the output patch setting in the output port S1-01. The DOL switch 25 is conveniently provided on the direct output setting screen, but may be provided on another setting screen or the panel shown in FIG.
[0026]
Next, FIG. 4 shows a flowchart of the direct output setting event process executed in the digital mixer 1 according to the present invention. However, the variables ICN, OCN, and OPN in each flow indicate the numbers of input channels, output channels, and output ports, respectively. Here, although there are a plurality of types of output channels and output ports, serial numbers are assigned. The variable OP (OPN) sets the output patch of each output port OPN, the variable DOP (ICN) sets the direct output of each input channel ICN, and the variable DOE (ICN) turns on the direct output of each input channel. DOL indicates on / off of the direct output link.
[0027]
The direct output setting screen shown in FIG. 8 is displayed on the display 16, the cursor is moved to the cursor frame of a desired input channel by the selection switch (SEL) 17 a or the cursor movement key 22 on the panel, and the rotary encoder 23 is operated. Then, when a desired output port is selected and the enter key 24 is operated to confirm, the direct output setting event process shown in FIG. 4 is started. Here, in the rotary encoder 23, an output port excluding an output port already set as a direct output destination in any other input channel can be selected as an output destination of the input channel. When the direct output setting event process is started, in step S10, the number of the input channel at the cursor position is set to ICN, and the determined output port number is set to OPN. Next, in step S11, it is determined whether or not the output port number OPN is “0”, that is, whether or not the output port is not selected. Here, if it is determined that it is not selected (OPN = 0), the process proceeds to step S12, and the direct output setting (DOP (ICN)) is set to “0”, that is, NONE. Next, in step S13, it is determined whether or not the direct output in the input channel ICN is ON (DOE (ICN) = 1). The on / off setting of the direct output determined here is the setting state of the input channel at that time, and is set by the direct output setting switch 21b. Here, if it is determined that the direct output in the input channel ICN is off (DOE (ICN) = 0), the direct output is set as it is because it was originally set to not perform the direct output. End event processing.
[0028]
If it is determined in step S13 that the direct output in the input channel ICN is on (DOE (ICN) = 1), the process branches to step S14 and the direct output link on / off setting is on. It is determined whether or not (DOL = 1). The setting of the direct output link determined here is the setting state at that time, and is set by the DOL switch 25. If it is determined that the direct output link is turned on, the process proceeds to step S15. In step 15, the direct output DOE (ICN) of the input channel is turned off in conjunction with the direct output setting DOP (ICN) being set to “0” (NONE). Next, the output patch 49 is connected according to the output patch setting (OP (OPN)) set by the output patch setting in step S16. When the direct output setting of the input channel is prioritized over the output patch setting of any output port in the output patch 49 at the start of execution of step S16, the output patch setting of the output port is restored. . If it is determined in step S14 that the direct output link is turned off, the process jumps to step S16, and the above-described processing is performed in step S16.
[0029]
If it is determined in step S11 that any output port number is set as the output destination, the process branches to step S17, and the direct output setting (DOP (ICN)) of the input channel is “0”. It is determined whether or not “” has been set. The direct output setting determined here is the setting state at that time, and if it is determined that the direct output setting (DOP (lCN)) has been set to “0”, the process branches to step S18. In step S18, it is determined whether the direct output link on / off setting is on (DOL = 1). The setting of the direct output link determined here is the setting state at that time, and if it is determined that the direct output link is set to ON, the process proceeds to step S19. In step S19, the branch condition in step S11 and step S17, that is, “the output destination of the direct output of the input channel has been newly changed from the non-selected state (NONE) to any output port”. In conjunction with this, the direct output of the channel is set to ON (DOE (ICN) ← 1).
[0030]
If it is determined in step S17 that the direct output setting (DOP (ICN)) is not set to “0” (NONE), or if it is determined in step S18 that the direct output link is turned off, When the process of S19 is completed, the process proceeds to step S20. In step S20, the output port number OPN fetched in step S10 is set as the output port number of direct output setting (DOP (ICN)) in the input channel. Next, in step S21, it is determined whether or not the direct output of the input channel is on (DOE (ICN) = 1). If it is determined that the output patch 49 is ON, the process proceeds to step S22, and the output patch 49 is connected according to the direct output setting (DOP (ICN)) of the input channel. As a result, the input channel is directly output to the set output port. In this case, the existing connection by the output patch setting of the output port OPN is released. If it is determined in step S21 that direct output (DOE (ICN)) is off, direct output is not performed, and the direct output setting event processing ends.
[0031]
Here, when the direct output is determined to be off (DOE (ICN) = 0) in step S21, the direct output setting DOP (ICN) of the input channel is originally other than NONE, and the direct output is When it is off (DOE (ICN) = 0) and the direct output setting DOP (ICN) of the input channel is changed from NONE to any output port, the direct output is off (DOE (ICN) = 0) and the direct output link is off (DOL = 0).
In the above embodiment, when the direct output link is on (DOL = 1), the setting of the direct output destination of the input channel is changed from non-selected (NONE) to any output port. Although the condition for turning on the direct output in conjunction with each other is set, the condition for the interlock may be that any output port (other than NONE) is set as the direct output destination of the input channel instead. In the direct output setting event process of FIG. 4, this change can be realized by executing step S18 immediately without performing the process of step S17 after the NO branch of step S11 as indicated by the broken line.
[0032]
Next, FIG. 5 shows a flowchart of output patch setting event processing executed in the digital mixer 1 according to the present invention.
In this output patch setting event processing, the output patch setting screen shown in FIG. 7 is displayed on the display 16, the cursor is moved to the cursor frame of any output port number by the cursor movement key 22, and the rotary encoder 23 is moved. When an output channel number as a desired input source is selected by operating and the enter key 24 is operated to confirm, the output patch setting event process shown in FIG. 5 is started. When the output patch setting event process is started, the output channel number selected in step S30 is set to OCN, and the selected output port number is set to OPN. Next, in step S31, output patch setting (OP (OPN)) is performed in which the currently selected output channel number OCN is set to the selected output port OPN.
[0033]
In step S32, whether or not there is a direct output setting DOP (ICN) in which DOP (ICN) = OPN, that is, the direct output setting with the output port OPN as an output destination is any of the following. It is determined whether or not the operation is performed on the input channel ICN. If it is determined that there is no input channel set to direct output at the output port OPN, the process proceeds to step S34, and the output patch 49 is connected according to the output patch setting (OP (OPN)), and the output patch is set. The setting event process ends. If it is determined that there is an input channel set to direct output at the output port OPN, the process branches to step S33 to determine whether direct output (DOE (ICN)) is set to ON for the input channel ICN. To be judged. If it is determined that the direct output (DOE (ICN)) is set to ON for the input channel ICN, the direct output setting is prioritized, and the output patch setting event process ends as it is. If it is determined that the direct output (DOE (ICN)) is not set to ON for the input channel ICN, the process branches to step S34 to connect the output patch 49 according to the output patch setting (OP (OPN)). Is done. As described above, the output patch 49 is set for an output port (an output port whose port number is DOP (ICN)) set to direct output in the input channel ICN in which direct output is set to ON (DOE (ICN) = 1). The output patch setting is not effective in. In this process, even if the enter key 24 is operated when the cursor is at the output port on the output patch setting screen for the port for which the direct output is valid, the output patch setting event process of FIG. May be protected from being executed, or the output patch setting event process may be executed but the value of OP (OPN) may not be changed in step S31. Even if an output patch setting is set for an output port for which direct output is valid, it will not be reflected in the output patch 49. Thus, it is preferable to prevent the user from changing the output patch setting on the output patch setting screen. Don't be confused.
[0034]
Next, FIG. 6 shows a flowchart of direct output on / off event processing executed in the digital mixer 1 according to the present invention.
When the direct output setting switch 21b is operated while the input channel is selected by the selection switch (SEL) 17a on the panel, the direct output on / off event process shown in FIG. 6 is started. When the direct output on / off setting event process is started, the number of the input channel selected by the selection switch 17a in step S40 is set to ICN. Next, in step S41, the on / off state of the direct output (DOE (ICN)) in the input channel ICN is inverted. This is because the direct output setting switch 21b is a toggle switch that reverses its state each time it is operated.
[0035]
Next, in step S42, it is determined whether or not the direct output setting (DOP (ICN)) in the input channel ICN is set to “0” (NONE). If it is determined that the direct output setting (DOP (ICN)) in the input channel ICN is set to “0” (NONE), the direct output (DOE (ICN)) is turned on / off. Since it has no meaning, the direct output on / off event processing ends as it is. If it is determined that the direct output setting (DOP (ICN)) in the input channel ICN is not “0”, the process proceeds to step S43, and whether the direct output (DOE (ICN)) in the input channel ICN is turned on. It is determined whether or not. If it is determined that the direct output (DOE (ICN)) is turned on, the process branches to step S45, and the output patch 49 is connected according to the direct output setting (DOP (ICN)) in the input channel ICN. Done. That is, when direct output of the input channel ICN is turned on by operating the direct output setting switch 21b, the input channel ICN is directly output to the set output port. In this case, the existing connection of the output port by the output patch setting is canceled.
[0036]
If it is determined that the direct output (DOE (ICN)) is turned off, the process proceeds to step S44, and the output patch setting (OP (OP ()) of the output port OPN indicated by the direct output setting DOP (ICN) of the input channel is reached. In accordance with OPN)), the output patch 49 is connected. That is, when the direct output of the input channel ICN is turned off by the operation of the direct output setting switch 21b, the output patch setting prioritized by the direct output setting of the input channel ICN is restored.
In the above description, when the direct output link switch 25 is turned on, the direct output is turned on / off in conjunction with the direct output setting. However, both direct output on and off are always linked. There is no need to link them, but only on may be linked or only off may be linked.
[0037]
【The invention's effect】
As described above, the present invention separately provides the output patch means capable of setting the output channel for each output port and the direct output setting means for setting the output port for each input channel and directly outputting the output channel. Each time there is provided a switch means that enables the setting of the direct output setting means in preference to the setting of the output patch means, and the output channel by the output patch setting and the input channel by the direct output setting are overlapped in one output port It is possible to set. Then, by operating the switch means for each input channel, it is possible to select either the direct output setting of the input channel or the output patch setting of the output destination output port of the same direct output setting. As a result, the direct output can be easily set, and the direct output can be quickly switched on / off.
[0038]
In addition, when link means for controlling ON / OFF of the direct output of the input channel in conjunction with the direct output setting of each input channel by the direct output setting means is provided, the direct output indicating any output port for each input channel. You can enable the direct output patch according to the set direct output setting of the input channel just by making the setting, and you can make the input just by making the direct output setting indicating non-selection. Channel direct output can be disabled.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a digital mixer which is an embodiment of a mixing apparatus of the present invention.
FIG. 2 is a diagram showing an outline of the appearance of a panel in a digital mixer according to the present invention.
FIG. 3 is an equivalent functional block diagram in which mixing processing is performed in the digital mixer having the configuration shown in FIG. 1 according to the present invention.
FIG. 4 is a flowchart of direct output setting event processing executed in the digital mixer according to the present invention.
FIG. 5 is a flowchart of output patch setting event processing executed in the digital mixer according to the present invention.
FIG. 6 is a flowchart of a direct output on / off event process executed in the digital mixer according to the present invention.
FIG. 7 is a diagram showing a display screen for setting an output patch in the digital mixer according to the present invention.
FIG. 8 is a diagram showing a display screen for direct output setting in the digital mixer according to the present invention.
[Explanation of symbols]
1 Digital mixer, 10 CPU, 11 Flash memory, 12 RAM, 13 Other I / O, 14 Waveform I / O, 15 Signal processor, 16 Display, 17 Electric fader, 17a Select switch, 17b Solo switch, 17c Channel switch , 18 controls, 20 display selection switch, 21 routing switch, 21a bus setting switch, 21b direct output setting switch, 22 cursor movement key, 23 rotary encoder, 24 enter key, 25 DOL switch, 26 tab selection switch, 40 analog Input section, 41 Digital input section, 42 Built-in effector, 43 Input patch, 44 Input channel section, 45 MIX bus, 46 AUX bus, 47 MIX output channel section, 48 AUX output channel section, 49 Output patch, 5 Analog output section, 51 a digital output unit, 53 a monitor selector, 54 monitoring mixer, analog output unit for 55 monitor

Claims (4)

Mixing bus means comprising a bus for mixing outputs from a plurality of input channels;
A plurality of output channels to which a mixing output from the mixing bus means is supplied;
A plurality of output ports each capable of outputting one signal;
Output patch setting means for setting one output channel of the plurality of output channels as an input source of a signal to the output port for each output port of the plurality of output ports;
For each input channel of the plurality of input channels, one output port of the plurality of output ports is selected and set as an output destination for directly outputting the signal of the input channel, or the signal of the input channel Direct output setting means for setting the output destination to output in a non-selected state ,
First switch means for designating on or off direct output set by the direct output setting means for each input channel of the plurality of input channels;
Second switch means for designating on or off a link function for controlling the first switch means in conjunction with the setting of the direct output setting means;
When the link function is designated to be turned on in the second switch means, the input is made in response to setting other than the non-selected state as the output destination by the direct output setting means in any input channel. Link means for controlling the first switch means so that direct output of the channel is turned on;
Directly connecting each input channel for which the direct output of the plurality of input channels is designated on to an output port designated as an output destination of the input channel by setting of the direct output setting unit, and Output patch means for patch-connecting each output port that is not connected by the direct connection among a plurality of output ports to an output channel set as an input source of the output port by setting of the output patch setting means,
A mixing apparatus characterized by comprising:   The direct output setting means is configured so that an output port that is already set as an output destination in any one of the plurality of input channels cannot be set as an output destination of another input channel. The mixing apparatus according to claim 1. When the link function is designated on the link means, the output port selected as the output destination in said direct output setting means in any of the input channels is changed from one output port to the other output port In this case, the first switch means is controlled so that the direct output of the input channel is turned on, assuming that the output destination of the input channel is set to a state other than the non-selected state. The mixing apparatus according to claim 1. When the link function is designated on the link means further, in response to the output destination is set to the non-selected state at the direct output setting means in any of the input channels, of the input channels mixing device according to any one of claims 1 to 3 direct output and controls said first switching means so as to be off-specification.

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