Abstract:
A mixing apparatus which makes it possible to monitor an internally-generated audio signal and an audio signal from an external apparatus not only in response to turning-on/off of a monitor switch but also in flexible and various manners when mixing those signals. The mixing apparatus is connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal. The input audio signals are mixed into a mixed audio signal. The mixed audio signal and an audio signal input from the external apparatus are mixed using a predetermined monitor mix balance into a monitor output signal. A monitor switch is operated to switch between a plurality of monitor states. The predetermined monitor mix balance is changed according to a monitor state after switching by the monitor switch.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     1. Field of the Invention  
         [0002]     The present invention relates to a mixing apparatus and a mixing method which can input and mix a plurality of audio signals and output the resulting mixed signal, as well as a program for implementing the mixing method. In particular, the present invention relates to a mixing apparatus and a mixing method which make it possible to set a plurality of monitor mix balances in mixing an internally generated audio signal and an audio signal from an external apparatus, as well as a program for implementing the mixing method.  
         [0003]     2. Description of the Related Art  
         [0004]     Conventionally, there has been known a mixing apparatus which inputs various audio signals (for example, audio signals collected by e.g. a microphone, audio signals output from various musical instruments, audio signals output from various MIDI tone generators, and audio signals output from a sequencer), mixes at least two audio signals thus input, and applies effects to an audio signal obtained by mixing and outputs the resulting mixed audio signal. In general, this mixing apparatus is provided with a plurality of monitor output terminals and a plurality of monitor switches. By turning on one of the monitor switches, it is possible to monitor a final stereo output via a speaker or a headphone connected to the monitor output terminal associated with the turned-on monitor switch, and therefore possible to check e.g. whether the condition of mixing is appropriate or not.  
         [0005]     On the other hand, in recent years, there has been known a so-called digital audio workstation (DAW) and an audio sequencer which realize various functions required for music production (for example, a hard disk recording function, a mixing function, and a MIDI equipment controlling function) by operating predetermined programs on a personal computer (PC). Also, there has been known a system in which the mixing apparatus and the DAW and/or the sequencer are connected to each other so that the mixing apparatus and the DAW and/or the sequencer can operate in cooperation with each other. The plurality of apparatuses are connected to each other via a network conforming to standards such as IEEE1394 so that a large quantity of data can be transferred at a high speed. An audio signal created by the DAW and/or the sequencer on the PC is input to the mixing apparatus, and further, at least two audio signals are input via a plurality of different input channels (for example, input channels of a microphone, a guitar, a synthesizer/tone generator, or other equipment) of the mixing apparatus, and the input two audio signals are mixed within the mixing apparatus, and effects are applied to the mixed audio signal, and the audio signal with the effects applied thereto and the audio signal from the DAW and/or the sequencer are mixed into a final output.  
         [0006]     By the way, as mentioned above, the monitoring function of the mixing apparatus only enables monitoring of a final stereo output when a monitor switch is turned on. Therefore, it is impossible to check only an audio signal generated by applying effects thereto within the mixing apparatus, or to check only an audio signal input from e.g. an external DAW. In the case where audio signals are input to the mixing apparatus via multiple channels, it is desirable that the monitoring function enables monitoring of the input audio signals in flexible and various manners.  
       SUMMARY OF THE INVENTION  
       [0007]     It is an object of the present invention to provide a mixing apparatus and a mixing method which make it possible to monitor an internally-generated audio signal and an audio signal from an external apparatus not only in response to turning-on/off of a monitor switch but also in flexible and various manners when mixing those signals, as well as a program for implementing the mixing method.  
         [0008]     To attain the above object, there is provided a mixing apparatus connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internal mixing device that mixes the input plurality of audio signals and generates a mixed audio signal, an input device that inputs an audio signal generated by the external apparatus, a monitor output signal generating device that mixes the mixed audio signal generated by the internal mixing device and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor outpu -signal, a monitor operating element that switches between a plurality of monitor states, and a changing device that changes the predetermined monitor mix balance according to a monitor state after switching by the monitor operating element.  
         [0009]     According to this arrangement, there are provided a plurality of monitor mix balances to be applied in mixing an audio signal internally generated in the mixing apparatus and an audio signal input from an external apparatus and outputting the resulting signal. As a result, output signals can be monitored in flexible and various manners; for example, it is possible to monitor only an internally-generated stereo signal, monitor only a stereo signal from an external apparatus, and monitor a signal obtained by mixing those signals in a predetermined balance.  
         [0010]     Preferably, the mixing apparatus further comprises a first setting device that sets monitor mix balances in respective ones of the monitor states.  
         [0011]     Preferably, the mixing apparatus further comprises a second setting device responsive to operation of a predetermined switch in setting the monitor mix balance, to set a default value of a monitor mix balance or a value of an even valance.  
         [0012]     To attain the above object, in a second aspect of the present invention, there is provided a mixing apparatus connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internal mixing device that mixes the input plurality of audio signals and generates a mixed audio signal, an input device that inputs an audio signal generated by the external apparatus, a monitor output signal generating device that mixes the mixed audio signal generated by the internal mixing device and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor operating element that alternately switches between a first monitor state and a second monitor state each time the monitor operating element is depressed, and a setting device that sets a first balance value as the monitor mix balance in the first monitor state, and sets a second balance value as the monitor mix balance in the second monitor state.  
         [0013]     According to this arrangement, the same effects can be provided as in the first aspect of the present invention.  
         [0014]     Preferably, the setting device comprises a balance value setting device operable when the monitor operating element is continuously depressed, to display a screen for setting the first balance value and the second balance value, and set the first balance value and the second balance value on the screen.  
         [0015]     Preferably, the mixing apparatus further comprises a monitor mix balance value setting device responsive to operation of a predetermined switch in setting the monitor mix balance, to set a default value of a monitor mix balance or an even balance value in response to operation of a predetermined switch.  
         [0016]     To attain the above object, in a third aspect of the present invention, there is provided a mixing apparatus connected to at least one external apparatus and at least one external recording apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising a recording audio signal generating and outputting device that generates an audio signal for recording from the input plurality of audio signals and outputs the generated audio signal to the external recording apparatus, a monitor audio signal generating device that internally generates an audio signal for monitoring from the input plurality of audio signals, an input device that inputs an audio signal generated by the external apparatus, a monitor output signal generating device that mixes the internally generated monitor audio signal and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor operating element that switches between a plurality of monitor states, and a changing device that changes the predetermined monitor mix balance according to a monitor state after switching by the monitor operating element.  
         [0017]     According to this arrangement, the same effects can be provided as in the first aspect of the present invention.  
         [0018]     To attain the above object, in a fourth aspect of the present invention, there is provided a mixing method applied to a mixing apparatus connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internally mixing step of mixing the input plurality of audio signals and generating a mixed audio signal, an input step of inputting an audio signal generated by the external apparatus, a monitor output signal generating step of mixing the mixed audio signal generated in the internally mixing step and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching step of switching between a plurality of monitor states, and a changing step of changing the predetermined monitor mix balance according to a monitor state after switching in the monitor state switching step.  
         [0019]     To attain the above object, in a fifth aspect of the present invention, there is provided a mixing method applied to a mixing apparatus connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internally mixing step of mixing the input plurality of audio signals and generating a mixed audio signal, an input step of inputting an audio signal generated by the external apparatus, a monitor output signal generating step of mixing the mixed audio signal generated in the internally mixing step and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching step of alternately switching between a first monitor state and a second monitor state, and a setting step of setting a first balance value as the monitor mix balance in the first monitor state, and setting a second balance value as the monitor mix balance in the second monitor state.  
         [0020]     To attain the above object, in a sixth aspect of the present invention, there is provided a mixing method applied to a mixing apparatus connected to at least one external apparatus and at least one external recording apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising a recording audio signal generating and outputting step of generating an audio signal for recording from the input plurality of audio signals and outputting the generated audio signal to the external recording apparatus, a monitor audio signal generating step of internally generating an audio signal for monitoring from the input plurality of audio signals, an input step of inputting an audio signal generated by the external apparatus, a monitor output signal generating step of mixing the internally generated monitor audio signal and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching step of switching between a plurality of monitor states, and a changing step of changing the predetermined monitor mix balance according to a monitor state after switching in the monitor state switching step.  
         [0021]     To attain the above object, in a seventh aspect of the present invention, there is provided a mixing program executed by a computer connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internally mixing module for mixing the input plurality of audio signals and generating a mixed audio signal, an input module for inputting an audio signal generated by the external apparatus, a monitor output signal generating module for mixing the mixed audio signal generated by the internally mixing module and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching module for switching between a plurality of monitor states, and a changing module for changing the predetermined monitor mix balance according to a monitor state after switching by the monitor state switching module.  
         [0022]     To attain the above object, in an eighth aspect of the present invention, there is provided a mixing program executed by a computer connected to at least one external apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising an internally mixing module for mixing the input plurality of audio signals and generating a mixed audio signal, an input module for inputting an audio signal generated by the external apparatus, a monitor output signal generating module for mixing the mixed audio signal generated in the internally mixing module and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching module for alternately switching between a first monitor state and a second monitor state, and a setting module for setting a first balance value as the monitor mix balance in the first monitor state, and setting a second balance value as the monitor mix balance in the second monitor state.  
         [0023]     To attain the above object, in a ninth aspect of the present invention, there is provided a mixing program executed by a computer connected to at least one external apparatus and at least one external recording apparatus, for inputting and mixing a plurality of audio signals and outputting a resulting mixed audio signal, comprising a recording audio signal generating and outputting module for generating an audio signal for recording from the input plurality of audio signals and outputting the generated audio signal to the external recording apparatus, a monitor audio signal generating module for internally generating an audio signal for monitoring from the input plurality of audio signals, an input module for inputting an audio signal generated by the external apparatus, a monitor output signal generating module for mixing the internally generated monitor audio signal and the audio signal input from the external apparatus by using a predetermined monitor mix balance to generate a monitor output signal, a monitor state switching module for switching between a plurality of monitor states, and a changing module for changing the predetermined monitor mix balance according to a monitor state after switching by the monitor state switching module.  
         [0024]     The above and other objects, features, and advantages of the invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0025]      FIG. 1  is a block diagram showing the construction of a mixing apparatus (digital mixer) according to an embodiment of the present invention;  
         [0026]      FIG. 2  is a diagram showing the flow of signals in the case where recording is carried out in a state in which the digital mixer and a digital audio workstation (DAW) are connected to each other;  
         [0027]      FIG. 3  is a view showing the appearance of a panel of the digital mixer;  
         [0028]      FIG. 4  is a view showing an example of a screen view on the panel of the digital mixer when monitor mix balances are set;  
         [0029]      FIG. 5  is a flow chart showing a monitor mix balance setting process; and  
         [0030]      FIG. 6  is a flow chart showing a continued part of the monitor mix balance setting process in  FIG. 5 . 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0031]     The present invention will now be described in detail with reference to the drawings showing a preferred embodiment thereof. In the drawings, elements and parts which are identical throughout the views are designated by identical reference numerals, and duplicate description thereof is omitted.  
         [0032]      FIG. 1  is a block diagram showing the construction of a mixing apparatus (digital mixer) according to an embodiment of the present invention. The digital mixer  100  is comprised of a central processing unit (CPU)  101 , a memory  102 , a communication interface (IEEE1394 I/F)  103 , a digital signal processor (DSP)  104 , an input unit  105 , an output unit  106 , and a mixing console  107 . Reference numeral  108  denotes a bus line that connects the component parts to each other.  
         [0033]     The CPU  101  is a controller that controls the overall operation of the digital mixer  100 . The memory  102  is comprised of a ROM that stores programs to be executed by the CPU  101 , and a RAM that is used as a working memory. The communication I/F  103  provides interface for connection to various external apparatuses (for example, a PC functioning as a DAW and/or a sequencer, an electronic musical instrument or an electronic apparatus such as a digital mixer, or various audio equipment). The communication I/F  103  provides interface for transferring a large quantity of data (such as audio data and MIDI data) according to IEEE1394 Standards. The DSP  104  carries out a mixing process and an effect-applying process on a signal input via the input unit  105  in accordance with an instruction from the CPU  101 , and outputs the resulting signal via the output unit  106 . The input unit  105  inputs a plurality of microphone signals, line signals, and so forth. The output unit  106  carries out digital-to-analog conversion of a signal output from the DSP  104  and outputs the resulting signal to e.g. a speaker. The mixing console  107  is operated by the user, and a plurality of controllers (such as an input fader  111  and rotary encoders  112 ) and a display  113  are provided on an external panel of the mixing console  107 .  
         [0034]      FIG. 2  shows the flow of signals in the case where hard disk recording is carried out in a state in which a DAW  200  is connected to the digital mixer  100  in  FIG. 1 . An audio signal is input from a microphone  221 , a guitar  222 , a synthesizer (Synth)/tone generator (TG)  223 , or other equipment  224  to the digital mixer  100 . This corresponds to the input of an audio signal via the input unit  105  and the communication interface  103  appearing in  FIG. 1 . In the digital mixer  100 , a process  211  in which equalizer processing (EQ) or dynamics processing is performed on the input audio signals as the need arises is carried out to control the tone quality and the volume. The audio signals with the tone quality and the volume thereof controlled are transferred to e.g. the DAW  200  via the communication I/F  103 , and the DAW  200  records them in respective tracks (a hard disk recording process  201 ). Alternatively, the audio signals are assigned to a recording bus within the digital mixer  100 , and collected into two channels (L/R), i.e. right and left channels and output to the DAW  200  via the communication I/F  103 , and recorded as a stereo track by the DAW  200  (the hard disk recording process  201 ).  
         [0035]     The DAW  200  which carries out recording is realized by executing a predetermined program on a PC. Also, the DAW  200  is capable of generating e.g. accompaniment tones using a synthesizer  202 , and outputting the accompaniment tones via an audio mixer  203 . During recording, the digital mixer  100  carries out an effect process  212  to apply effects such as balances and reverberations to audio signals different from tones which are to be recorded so that a player can easily perform a piece of music.  
         [0036]     The digital mixer  100  then mixes an output  213  thus internally generated and an audio signal  214  output from the DAW  200  ( 215 ), and then outputs the resulting audio signal to a monitor speaker  216  (or a headphone or the like). As a result, it is possible to record input performance tones from the microphone  221 , the guitar  222 , or the like while monitoring accompaniment tones generated by the synthesizer  202  of the DAW  200 .  
         [0037]     It should be noted that the process  211  such as EQ (equalizer) processing, effect process  212 , mixing process  215 , and so forth are carried out in the digital mixer  100  by the DSP  104  in  FIG. 1  according to an instruction from the CPU  101 .  
         [0038]     Further, although  FIG. 2  shows an example of hard disk recording, the digital mixer  100  may perform a mixing-down process in which a recorded audio signal and a separately input audio signal are controlled as a whole while being monitored, and a final stereo output is recorded. Further, the digital mixer  100  may be used alone without being connected to the DAW  200 .  
         [0039]      FIG. 3  shows the appearance of a panel  300  of the digital mixer  100 . Reference numeral  301  denotes a display ( 113  in  FIG. 1 ), and reference numeral  302  denotes eight rotary encoders. Numerals  1  to  8  given above the respective rotary encoders  302  indicate the respective positions of them. The rotary encoders  302  will hereinafter be referred to as RE 1  to RE 8 , respectively. Each RE is provided with a plurality of LEDs as indicators that indicate the level of a parameter controlled by the RE and are arranged around a knob rotated by the user. Each RE also serves as a push switch that is turned on by depressing the knob. Reference numeral  303  denotes eight input faders which are used for adjusting e.g. the volume level for each channel. Reference numreal  304  denotes a fader which controls the volume level of a stereo output obtained as a result of mixing. Reference numeral  305  denotes a monitor switch;  306 , a shift switch; and  307 , a volume for controlling the monitor output level. The monitor switch  305  and the shift switch  306  are each provided with an LED which indicates an on/off state.  
         [0040]     It should be noted that operating elements (for example, an operating element for directly controlling the DAW connected to the digital mixer  100 ) other than the operating elements appearing in  FIG. 3  are actually provided on the panel  300  of the digital mixer  100 , but description thereof is omitted.  
         [0041]     With the digital mixer  100 , a speaker or a headphone for monitoring ( 216  in  FIG. 2 ) can be connected to a monitor-out/headphone-out output terminal, not shown, so that output signals can be monitored. In particular, depending on whether the monitor switch  305  is on (the LED is on) or off (the LED is off), there can be two kinds of balances applied when mixing a stereo signal generated inside the digital mixer  100  and a stereo signal from the DAW  200  and outputting the resulting signal. The LED of the monitor switch  305  is alternately turned on or off each time the monitor switch  305  is depressed. It should be noted that in the present embodiment, the expression “the monitor switch  305  is on” does not mean “there is no monitor output”. Irrespective of whether the monitor switch  305  is on (the LED is on) or off (the LED is off), there is a monitor output. According to whether the monitor switch  305  is on or off, the balance in mixing a stereo signal generated inside the digital mixer  100  and a stereo signal from the DAW  200  and outputting the resulting signal is changed.  
         [0042]     Further, by continuously depressing the monitor switch  305 , a screen as shown in  FIG. 4  is displayed so that the balance in the case where the LED of the monitor switch  305  is on and the balance in the case where the LED of the monitor switch  305  is off can be set. In  FIG. 4 , reference numeral  411  denotes a message displayed to indicate that the present screen is a monitor mix balance setting screen. Reference numeral  413  denotes the present set value of the monitor mix balance in the case where the LED of the monitor switch  305  is off (off). “INT&gt;126” indicates that the value of the monitor level of a stereo signal ( 213  in  FIG. 2 ) generated inside the digital mixer  100  is 126, and “0&lt;DAW” indicates that the value of the monitor level of a stereo signal ( 214  in  FIG. 2 ) from the DAW  200  is 0. Similarly, reference numeral  415  indicates the present set value of the monitor mix balance in the case where the LED of the monitor switch  305  is on (on). “INT&gt;63” indicates that the value of the monitor level of a stereo signal generated inside the digital mixer  100  is 63, and “63&lt;DAW” indicates that the value of the monitor level of a stereo signal from the DAW  200  is 63.  
         [0043]     By rotating the RE  5  below the display  413  in the state shown in  FIG. 4 , it is possible to change the monitor mix balance indicated by the display  413 . Similarly, by rotating the RE  7 , it is possible to change the monitor mix balance indicated by the display  415 . Further, by depressing the knobs of the RE 5  and RE 7 , it is possible to set the monitor mix balances thereof to an even balance. The even balance is represented by “INT&gt;63:63&lt;DAW”. Further, by depressing the RE 5  while depressing the shift switch  306 , a predetermined default value is set as the monitor mix balance. This also applies to the RE 7 .  
         [0044]      FIGS. 5 and 6  show a monitor mix balance setting process. This process is activated by the CPU  101  when the monitor switch  305  is operated. First, in a step S 501 , an event search is carried out with respect to an operation performed by the user. In a step S 502 , it is determined whether or not the LED of the monitor switch  305  is on. If the LED of the monitor switch  305  is on, it is then determined whether or not the operation performed by the user is a click-on event of the monitor switch  305  (an operation in which the monitor switch  305  is released immediately after it is depressed). If the operation performed by the user is the click-on event, the LED of the monitor switch  305  is turned off in a step S 504 . Then, in a step S 505 , monitor data B is transferred to the DSP  104 . The monitor data B is the value of the monitor mix balance (the set value indicated by the display  413  in  FIG. 4 ) in the state in which the LED of the monitor switch  305  is off. The value of the monitor mix balance of the monitor data B is transferred to the DSP  104  so that the monitor mix balance is set to the transferred value, i.e. set value. After execution of the step S 505 , the process is terminated.  
         [0045]     If it is determined in the step S 502  that the LED of the monitor switch  305  is off, it is then determined in a step S 506  whether or not the operation performed by the user is the click-on event. If the operation performed by the user is the click-on event, the LED of the monitor switch  305  is turned on in a step S 507 . Then, in a step S 508 , monitor data A is transferred to the DSP  104 . The monitor data A is the value of the monitor mix balance (the set value indicated by the display  415  in  FIG. 4 ) in the state in which the LED of the monitor switch  305  is on. The value of the monitor mix balance of the monitor data A is transferred to the DSP  104  so that the monitor mix balance is set to the transferred value, i.e. set value. After execution of the step S 508 , the process is terminated.  
         [0046]     If it is determined in the step S 503  or S 506  that the operation performed by the user is not the click-on event, it is then determined in a step S 509  whether or not the monitor switch  305  is being depressed. If the monitor switch  305  is not being depressed, the process is immediately terminated. If the monitor switch  305  is being depressed, the monitor mix balance setting screen shown in  FIG. 4  is displayed in a step S 510 . The display  413  indicates the set value of the monitor data B, and the display  415  indicates the set value of the monitor data A.  
         [0047]     After execution of the step S 510 , it is determined in a step S 601  whether or not a RE 5  rotating event has occurred. If the RE 5  rotating event has occurred, the following operations are performed: INTVOLa←INTVOLa+M and DAWVOLa←126-INTVOLa, where M indicates the operated amount of the RE 5 . “INTVOLa” indicates a work register that stores the value of the monitor level of the stereo signal  213  generated inside the digital mixer  100  when the LED of the monitor switch  305  is off, and “DAWVOLa” indicates a work register that stores the value of the monitor level of the stereo signal  214  from the DAW. After execution of the step S 602 , the values of INTVOLa and DAWVOLa are set to the monitor data A and stored, and the stored set values (INTVOLa and DAWVOLa) of the monitor mix balance are indicated by the display  413  in  FIG. 4  in a step S 603 .  
         [0048]     If it is determined in the step S 601  that the RE 5  rotating event has not occurred, it is then determined in a step S 604  whether or not a push event has occurred in which the knob of the RE 5  is pushed. If the push event has occured, it is determined in a step S 605  whether the shift switch  306  is on or off. If the shift switch  306  is on, the default value of the monitor mix balance in the case where the LED of the monitor switch  305  is off is set in INTVOLA and DAWVOLa, and the process proceeds to the step S 603 . If the shift switch  306  is off, the even valance i.e. 63 is set in INTVOLa and DAWVOLa in a step S 607 , and the process proceeds to the step S 603 .  
         [0049]     Steps S 611  to S 617  correspond in processing to the steps S 601  to S 607 , respectively (blocks whose step numbers have the same ones digits correspond to each other). In the steps S 611  to S 617 , however, the mix balance in the case where the LED of the monitor switch  305  is on is set, and hence the RE 7  is used in place of the RE 5 , INTVOLb is used in place of INTVOLa, DAWVOLb is used in place of DAWVOLa, and the monitor data B is used in place of the monitor data A. Also, the default value set in the step S 616  is opposite in balance state to the default value set in the step S 606 .  
         [0050]     As described hereinabove, according to the present embodiment, there are provided plural kinds of monitor mix balances to be applied in mixing an audio signal generated inside the digital mixer and an audio signal input from an external apparatus and outputting the resulting signal. As a result, output signals can be monitored in flexible and various manners; for example, it is possible to monitor only a stereo signal generated inside the digital mixer, monitor only a stereo signal from an external apparatus, or monitor a signal obtained by mixing those stereo signals in a predetermined balance.  
         [0051]     It should be noted that in the above described embodiment, although the DAW is given as an example of an external apparatus connected to the digital mixer, other external apparatuses may be used.  
         [0052]     Further, although two kinds of monitor mix balances are provided depending on whether the monitor switch  305  is on or off, other monitor mix balances may be additionally used. The default values set in the steps S 606  and S 616  are not limitative, but may be any values.  
         [0053]     It is to be understood that the object of the present invention may also be accomplished by supplying a system or an apparatus with a storage medium in which a program code of software, which realizes the functions of the above described embodiment is stored, and causing a computer (or CPU or MPU) of the system or apparatus to read out and execute the program code stored in the storage medium.  
         [0054]     In this case, the program code itself read from the storage medium realizes the functions of the above described embodiment, and hence the program code and a storage medium in which the program code is stored constitute the present invention.  
         [0055]     Examples of the storage medium for supplying the program code include a floppy (registered trademark) disk, a hard disk, a magneto-optical disk, a CD-ROM, a CD-R, a CD-RW, a DVD-ROM, a DVD-RAM, a DVD-RW, a DVD+RW, a magnetic tape, a nonvolatile memory card, and a ROM. Alternatively, the program code may be supplied by downloading via a network.  
         [0056]     Further, it is to be understood that the functions of the above described embodiment may be accomplished not only by executing a program code read out by a computer, but also by causing an OS (operating system) or the like which operates on the computer to perform a part or all of the actual operations based on instructions of the program code.  
         [0057]     Further, it is to be understood that the functions of the above described embodiment may be accomplished by writing the program code read out from the storage medium into a memory provided in an expansion board inserted into a computer or a memory provided in an expansion unit connected to the computer and then causing a CPU or the like provided in the expansion board or the expansion unit to perform a part or all of the actual operations based on instructions of the program code.