JP2007293312A - Music processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To restore a music function of a musical instrument when archiving a project file. <P>SOLUTION: When a project file has been read which includes track data, identification information of a currently-set external equipment and parameters of the external equipment, any one of musical instruments connected to a music LAN 30 is detected and the detected external equipment is associated with any one of external equipment which had been set for use when storing the project file. By transferring parameters stored in a parameter storage means to the external equipment that has been associated, and by synchronizing the parameter between the external equipment and the parameter storage means, the music function when archiving can be restored about an existing musical instrument which could be associated. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention can execute a series of music processing such as recording / playback, editing, and mixing of performance events and audio signals, and the music can be provided by externally connecting a music device having a predetermined music function. The present invention relates to a music processing apparatus that can use the music function of a device as part of the music processing.

  Conventionally, application software installed in a personal computer (hereinafter referred to as “personal computer”) called DAW (Digital Audio Warkstation) is known. The personal computer on which the DAW is activated operates as a music processing apparatus, and can perform a series of music processing such as recording / playback, editing, and mixing of MIDI events and audio signals. In this music processing apparatus, for each music file, a MIDI track for recording a MIDI event, an audio track for recording an audio signal, and a bus for mixing the audio signal are created and recorded on each track. A MIDI channel strip and an audio channel strip are created corresponding to each track. The MIDI channel strip is provided with an operator, and the volume (expression) and localization (pan) of a MIDI event reproduced on the corresponding MIDI track are controlled according to the operation of the operator. . In addition, the frequency characteristics, volume, and localization of the audio signal are controlled in accordance with the operation of an operator provided in the audio channel strip.

  The music processing apparatus is provided with an instrument plug-in and an effector plug-in to add functions. A plug-in is a program that provides additional functions to application software. By using a musical instrument plug-in, an analog synthesizer or sampler, or a software sound source dedicated to a piano or guitar (hereinafter referred to as “soft sound source”) can be used for music processing. Can be added to the device. In addition, a software effector (hereinafter referred to as “soft effector”) such as a reverb, a compressor, and an equalizer can be added to the music processing device by an effector plug-in. When using a software sound source added by an instrument plug-in, a registration screen is opened by opening a registration screen in the music processing apparatus. Also, when using a soft effector added by an effector plug-in, an insertion process for inserting a soft effector into a desired audio channel is performed. By executing the registration process or insertion process, the instrument plug-in or effector plug-in program is executed, and the port for transferring data between the music processing device and the software sound source or software effector is set. Will come to be. The name of the soft sound source or the name of the software effector is given to this port by performing the registration process.

  Furthermore, a hardware sound source (hereinafter referred to as “hard sound source”) and a hardware effect device (hereinafter referred to as “hard effect device”) are added to the music processing apparatus by externally connecting a hardware music device. Can do. When a music device is externally connected to the music processing device, the port is set based on the port related information acquired by the music processing device inquiring of the music device. Further, when using a hardware sound source added by external connection, a registration screen may be opened by opening a registration screen in the music processing apparatus. Further, when using a hardware effector added by external connection, an insertion process for inserting the hardware effector into a desired audio channel is performed. As described above, various sound sources can be added to the music processing device by adding the hardware sound source, and various effect devices can be added to the music processing device by adding the hardware effect device. .

  In a conventional music processing device, a music device can be externally connected and its music function can be used as part of the music processing. However, every time the music processing device is activated, the externally connected music device is set. Things get complicated. Therefore, it is proposed that the music device used in the music processing device and the setting data set in the music device are saved in the project file, and the project file is read to reproduce the state of the music processing device. ing. However, in a music LAN (Local Area Network) in which a music device is externally connected to a music processing device, logical paths between the music processing device and the music device are sequentially set according to a user instruction. Whether to exchange data using the target path varies depending on the order in which the user has instructed the connection. In addition, when each music device of the music LAN is turned on, the logical path at the time of the previous power-off is automatically restored. Which music device uses which logical path depends on each music device. Fluctuates depending on the timing when is turned on. Thus, even if the user turns on the power of the music device in the same order, the same logical path as the previous time is not always set. Also, when restoring the state of the music processing device, the parameters that control the operation of the music device may have changed since the project file was saved, and the music function of the music device when the project file was saved There was a problem that it was not restored and it became a different music function.

  Accordingly, an object of the present invention is to provide a music processing apparatus that can restore a music function of a music device when a project file is saved by reading the project file.

  In order to achieve the above object, the music processing apparatus of the present invention is detected when a project file including track data, specific information of an external device set to be used, and parameters of the external device is read. The external device is associated with the external device that is set to be used when the project file is saved, and the parameters stored in the parameter storage unit are transferred to the external device that can be associated with each other. The main feature is that the parameters are synchronized between the storage means.

  The present invention sets the use of the detected external device when saving the project file when the project file including the track data, the specific information of the external device set to be used, and the parameters of the external device is read. The parameters are synchronized between the external device and the parameter storage unit by associating the external device with the associated external device and transferring the parameter stored in the parameter storage unit to the associated external device. Therefore, it is possible to restore the music function at the time of storage for the existing music device that can be associated.

The configuration of an embodiment of the music processing apparatus of the present invention is shown in FIG. A music processing apparatus 1 shown in FIG. 1 is realized by starting application software called DAW (Digital Audio Warkstation) on an OS (Operating System) of a personal computer (PC). That is, the music processing apparatus 1 is realized by the personal computer PC on which the DAW 2 is operating. The music processing apparatus 1 can execute a series of music processing such as recording / playback, editing, and mixing of MIDI events and audio signals.
In the music processing apparatus 1, the user can create any number of MIDI tracks for recording MIDI events, audio tracks for recording audio signals, and buses for mixing audio signals for each music file called a project. Has been. The MIDI track can selectively record a MIDI event input from one or more MIDI input ports / channels of the music processing apparatus 1 for each MIDI track, and is played back on the MIDI track. As an event output destination, any one of a plurality of MIDI output ports / channels provided in the music processing apparatus 1 can be selected. Each time the user creates a MIDI track, a corresponding MIDI channel strip display is added to the MIDI mixer screen.

  Therefore, there are MIDI channel strips corresponding to the output of each MIDI track on the MIDI mixer screen, and the user can create an arbitrary number of MIDI channel strips on the MIDI mixer screen. In each of the former MIDI channel strips, the user can arbitrarily select the output destination of the MIDI event, and in each of the latter MIDI channel strips, the user can arbitrarily specify the input source of the MIDI event and the output destination of the MIDI event. The volume (expression), localization (pan), and mute of the MIDI event played on the corresponding MIDI track can be controlled according to the operation of the controls provided on each MIDI channel strip. be able to.

  The audio track is an audio signal input source for recording, and any one of a plurality of audio input ports or audio mixer buses provided in the music processing device 1 is provided for each audio track. The user can select. In addition, as an output destination of the audio signal reproduced on the audio track (output destination of the corresponding audio channel), the user selects an arbitrary one from a plurality of audio output ports provided in the music processing apparatus 1 or an audio mixer bus. Being able to choose. In this case, an audio channel is automatically inserted between the audio track and the selected output destination. Each time the user creates an audio track, a corresponding audio channel strip display is added to the audio mixer screen. Further, each time a user creates a bus, an audio channel strip display corresponding to the output of the bus is added to the audio mixer screen. Therefore, an audio channel strip corresponding to each audio track and each bus exists on the audio mixer screen.

  In addition, the user can create any number of audio channel strips. In the former (audio track and bus) audio channel strips, the output destination can be arbitrarily selected, and in the latter audio channel strips, the input source and the output destination can be arbitrarily selected. Specifically, in the channel strip of each audio channel, any one of a plurality of audio input ports, audio tracks, and audio mixer buses provided in the music processing apparatus 1 can be selected as an audio signal input source. In addition, any one of a plurality of audio output ports provided in the music processing apparatus 1 or an audio mixer bus can be selected as an output destination of the audio signal. Then, the frequency characteristics, volume, and localization of the audio signal in the corresponding audio channel can be controlled according to the operation of the operator provided in each audio channel strip on the audio mixer screen. Each bus mixes one or more input audio signals, and the mixed audio signals are supplied to corresponding audio channel strips.

  In such a music processing apparatus 1, a software sound source (hereinafter referred to as “soft sound source”) can be added by plug-in, and a software effect device (hereinafter referred to as “soft effect device”) can be added by plug-in. can do. A software sound source is provided by a musical instrument plug-in, and a software sound source (musical instrument) dedicated to an analog synthesizer, a sampler, or a piano or a guitar can be added to the music processing apparatus 1 by the musical instrument plug-in. The soft effect device is provided by an effect plug-in, and a soft effect device such as a reverb, a compressor, or an equalizer can be added to the music processing apparatus 1. The plug-in is a program for providing an additional function to the application software (DAW).

  The instrument plug-in will be described. When one or more instrument plug-in software files are placed in a predetermined folder of the music processing apparatus 1 and the DAW 2 is started up, the information of the instrument plug-in software is read into the DAW 2 and the DAW 2 rack The name of the software sound source (instrument) corresponding to the instrument plug-in software is added to the sound source menu displayed in the sound source rack that is an object so that it can be selected. When the soft sound source is selected in the sound source menu and registered in the sound source rack, the soft sound source program is activated, and one or more MIDI output ports / channels and audio input ports are generated. In this case, the MIDI output port / channel is a virtual port for the DAW 2 to supply a MIDI event to the software sound source, and the audio input port is a port for receiving an audio signal (musical sound) generated by the software sound source. is there. The name of the software sound source (musical instrument) is given to the MIDI output port and the audio input port. Thus, since the name of the software sound source (instrument) is attached to the port when selecting, each MIDI track or MIDI channel can easily set the MIDI output port for the software sound source as the output destination of the MIDI event. The audio input port for the soft sound source can be easily selected as the input source of the audio signal in each audio track or audio channel. The registered soft sound source generates and mixes one or a plurality of audio signals according to the MIDI event supplied from the DAW 2 to the soft sound source via the MIDI output port, and the mixed audio signal is sent to the audio input port. To output to DAW2.

  Each instrument plug-in software includes an editor program. By opening the editor's parameter editing screen for each software sound source registered in the sound source rack, the timbre parameters, sound source parameters, etc. The operation data can be edited. The parameter editing screen includes an edit button prepared for each software sound source registered on the sound source rack display screen, and an edit button provided on the MIDI track display screen in which the software sound source is set as a MIDI event output destination. The software sound source is opened when one of the edit buttons prepared on the display screen of the audio channel strip set as the audio signal input source is operated.

  Next, the effect plug-in will be described. When one or more effect plug-in software files are placed in a predetermined folder of the music processing apparatus 1 and the DAW 2 is started, the information on the effect plug-in software is read into the DAW 2. , The name of the software effector corresponding to the effector plug-in software is added to the effector menu displayed in the insertion setting section of the audio channel strip of the DAW 2 so that it can be selected. When the soft effector is selected in the effector menu and inserted into an audio channel strip, the softeffector program is launched and one or more audio output ports and audio input ports are created, The output terminal immediately before the insertion point in the audio channel is connected, and the input terminal immediately after the insertion point is connected to the audio input port. This inserts a soft effector into the audio channel. The inserted audio effector receives the audio signal from the process immediately before the insertion point in the audio channel, and the effect-applied audio signal is applied to the insertion point of the audio channel. Output to the next process. Each effector plug-in software includes an editor program, and operation data such as effect parameters can be edited by opening the parameter editing screen of the corresponding editor of each inserted software effector. . The parameter editing screen is opened when the effect editor and button of the audio channel strip in which the soft effector is inserted are operated.

  In addition, hardware music devices 31 to 34, which are external devices, are externally connected to the music processing apparatus 1 and corresponding device data is set, so that hardware sound sources (hereinafter referred to as “hard sound sources”) and hardware are set. An effector (hereinafter referred to as “hard effector”) can be added. By connecting the music devices 31 to 34 to the music processing apparatus 1 and setting device data, a hardware sound source such as a waveform memory sound source or a physical model sound source, a synthesizer with a keyboard, or an instrument such as an electronic piano or electronic guitar, and A hardware effector such as a reverb, a compressor, or an equalizer can be added to the music processing apparatus 1. When music devices 31 to 33 are externally connected to the music processing apparatus 1 via the music LAN 30, a logical path for exchanging data of MIDI events and audio signals is automatically or manually set. 33, based on the information acquired by inquiring the music processing apparatus 1 to 33, the device name of the device, the association with the control editor (remote control software), the MIDI input / output port and the audio input / output port The number of ports is set and the individual association between the music device and the port is set. Note that the port functions as a sub address of the logical path. As for the music device 34 connected to the MIDI output port or the analog input / output port which is a static port, since the music processing apparatus 1 cannot obtain such information from the music device 34, it corresponds to the device name and the editor. The settings such as attachment, number of ports, and association with ports are performed manually. Then, when using the hardware sound source of the music devices 31 to 34 for which the corresponding device data is set, the hardware sound source may be registered by opening the registration screen of the sound source rack in the music processing apparatus 1. As a result, each MIDI track or MIDI channel strip can select the MIDI output port to which the hardware sound source is connected as the output destination of the MIDI event by the device name of the hardware sound source. In an audio track or an audio channel strip, an audio input port to which the hardware sound source is connected can be selected as an audio signal input source according to the device name of the hardware sound source. In this case, the name of the port for the music device that is the hardware sound source is changed to the name of the hardware sound source (instrument) when it is registered in the sound source rack, and the name of the port for the music device of the hardware effect device is the audio name. When inserted into a channel, it will be replaced with the name of the hardware effector. As described above, since the name of the hardware sound source (instrument) is attached to the port, the port can be easily selected when selecting. The registered hardware sound source generates and mixes one or a plurality of audio signals according to the MIDI event input to the hardware sound source via the MIDI output port of the music processing apparatus 1, and the mixed audio signal is audio. The data is output to the music processing apparatus 1 via the input port.

Furthermore, when using a hardware effector added by external connection, an insertion process for inserting a hardware effector at an insertion point of a desired audio channel may be performed. Here, as long as the device name of the hardware effector and the association with the port are set, the insertion instruction can be given by the device name of the effector. The output terminal immediately before the insertion point of the audio channel is connected to the audio output port of the instructed effector, and the input terminal immediately after the insertion point is connected to the audio input port. This inserts a hard effector into the audio channel strip. The audio signal from the process immediately before the insertion point in the audio channel is input to the inserted hardware effector, and the audio signal that has been subjected to a predetermined effect applying process is added to the insertion point of the audio channel. Output to the next process.
It should be noted that the hardware sound source parameter editing and the hardware effector parameter editing can be performed in the same manner as the software sound source and the software effector.
As described above, various sound sources (musical instruments) can be added to the music processing apparatus 1 by adding instrument plug-ins and hardware sound sources, and various effect devices can be added by adding effect plug-ins and hardware effect devices. Can be added to the music processing apparatus 1.

  Returning to FIG. 1, the DAW 2 in the music processing apparatus 1 includes a GUI control unit 11. The GUI (Graphical User Interface) in the GUI control unit 11 is a user interface that can use most graphics for displaying information to the user and perform most operations with a pointing device such as a mouse. The GUI control unit 11 displays various settings in various instrument plug-ins 12, MIDI track & MIDI mixer control unit 13, remote control unit 14, audio track & audio mixer control unit 15 and various effect plug-ins 16 by the GUI control unit 11. It can be performed by a simple operation by operating a mouse or the like on the setting screen. As a result, the above-described selection, setting, parameter editing, and the like can be performed by operating a mouse or the like on the screen displayed by the GUI control unit 11.

The various instrument plug-ins 12 are composed of the instrument plug-in software registered and activated in the sound source rack among the instrument plug-in software whose files are placed in the plug-in folder. Of the effector plug-in software in which files are placed in the in-folder, the effector plug-in software is inserted into the audio channel strip and activated.
The MIDI track & MIDI mixer control unit 13 also includes a MIDI track and a MIDI mixer including settings of the MIDI event input source and output destination in each MIDI track, and the MIDI channel MIDI event input source and output destination in the MIDI mixer. As with other various settings, the user can set the MIDI event input source and output destination by operating the mouse or the like on the setting screen displayed by the GUI control unit 11. .
The audio track & audio mixer control unit 15 controls the audio track and the audio mixer including the input source and output destination of each audio track, and the input source and output destination of the bus in the audio mixer. As with other settings, the user can set the output destination by operating the mouse or the like on the setting screen displayed by the GUI control unit 11.

  The remote control unit 14 can control each parameter and various settings of the music devices 31 to 34 externally connected to the music processing apparatus 1. In this case, the remote control unit 14 communicates with the music devices 31 to 34 by serial communication so that each parameter and various settings of the music devices 31 to 34 can be performed. In this remote control unit 14, an edit button for the music devices 31 to 34 is operated to open an editing screen, and the user operates the mouse or the like on this editing screen to edit parameters of the music devices 31 to 34. A setting instruction for various settings is issued. The remote control unit 14 may communicate with the music devices 31 to 34 through the MIDI communication path.

  An OS (Operating System) API (Application Programming Interface) 17 is interposed between the MIDI track & MIDI mixer controller 13, the remote controller 14, the audio track & audio mixer controller 15 and the driver group 20 in the DAW 2. Yes. An API is an entry point of functions prepared by an OS or programming language that can be used from an application, and is provided as a function for file control, window control, image processing, character control, and the like. The driver group 20 includes a plurality of types of drivers that are software for operating the connected music devices 31 to 34. The prepared drivers include various MIDI drivers 21 for various MIDI devices, serial drivers, and the like. The S communication driver for communication and various WAVE drivers for various audio devices are used. And it connects with the music apparatuses 31-34 by the various music I / O25 prepared for the music processing apparatus 1. FIG. The various music I / O 25 includes at least a MIDII / O port, a serial I / O port, and an audio I / O port. A music device having an interface that can be directly connected, such as a music device 34, is directly connected to the various music I / Os 25 prepared in the music processing apparatus 1. Also, a music LAN (Local Area Network) 30 is connected to the various music I / Os 25, and music devices 31, 32, 33 are connected to the network of the music LAN 30. The music LAN 30 is composed of IEEE 1396, USB (Universal Serial Bus), Ethernet, mLAN (registered trademark), and the like, and is a music network capable of transmitting MIDI events, audio signals, serial signals, and the like in real time. Each music device connected to the music LAN is provided with a logical input / output port for transmitting MIDI events, audio signals, serial signals, and the like in hardware. A logical input / output port is generated by software in accordance with the music device to be connected, and a logical event or audio signal is transmitted between the music processing apparatus 1 and the input / output port of each music device. Connection is made.

  As a result, when one of the music devices 31 to 34 is set as an input source of a certain MIDI track, for example, a MIDI event from the MIDI output port of the music device 31 to 33 that is a MIDI keyboard is used for various music. It is taken into the music processing apparatus 1 from the MIDI input port in the I / O 25, passed to the DAW 2 by the functions of the various MIDI drivers 21 and the API 17 of the OS, and taken into the MIDI track by the control of the MIDI track & MIDI mixer control unit 13. Become. In addition, a MIDI output port connected to the MIDI input port of the hardware device 31 to 33 is set as a MIDI event output destination of a certain MIDI track, and the audio signal of the bus of a certain audio track / audio mixer is set. When the audio input port connected to the audio output port of the music device 31 to 33 of the hardware sound source is set as the input source, the MIDI output from the MIDI track is controlled by the MIDI track & MIDI mixer control unit 13. The event is passed to various music I / Os 25 by the functions of the OS API 17 and various MIDI drivers 21 and supplied to the music devices 31 to 34 of the hardware sound source via the MIDI output port. In the hardware sound source, one or a plurality of audio signals (musical sounds) are generated based on the supplied MIDI event, and the audio signals are captured from the audio input ports of various music I / Os 25. The captured audio signal is passed to the DAW 2 by the functions of the various WAVE drivers 23 and the API 17 of the OS, and is captured by the audio track / audio mixer bus set by the control of the audio track & audio mixer control unit 15. .

In addition, the remote control unit 14 that performs various parameters and various settings of the music devices 31 to 34 externally connected to the music processing apparatus 1 uses the serial communication I / O port in the S communication driver 22 and various music I / O 25. Thus, by performing serial communication with the music devices 31 to 34 for performing various settings, the parameters of the music devices 31 to 34 are edited and various settings are performed. The music processing apparatus 1 is provided with a parameter memory for storing parameters of the music devices 31 to 34. The parameter memory is a non-volatile or volatile storage device that is readable and writable provided in the personal computer PC that implements the music processing apparatus 1. Here, FIG. 28 is a block diagram showing a configuration example of a personal computer PC that implements the music processing apparatus 1. A personal computer PC shown in FIG. 28 has a RAM (Random Access Memory) 4, which is a volatile storage device that functions as a work memory at the time of program operation, a nonvolatile storage device such as a hard disk 3a and a flash memory 3b, and a central processing operation. A device (CPU) 5, a ROM (Read Only Memory) 6 storing a boot program and the like, a display 7 such as a liquid crystal display (LCD) for displaying various operation screens and various information, and a controller such as a keyboard and a mouse. 8. Consists of an interface unit 9 (including various music I / O 25) for connecting external devices such as music devices 31 to 34 to communicate with these devices. The CPU 5 and each unit are connected by a bus (not shown). Are connected to each other. Files in which programs such as the OS, DAW2 (application software), and various plug-in software are recorded are readable and stored in a predetermined folder on the hard disk 3a or the flash memory 3b. The CPU 5 reads these files as appropriate, By executing processing based on each program, the personal computer PC functions as the music processing apparatus 1.
If any of the music devices 31 to 34 externally connected to the music processing device 1 is disconnected due to an erroneous operation or an accident, the disconnected music device is set in a dummy state and cannot be used. In this case, the port set in the music device is set in the dummy state, and operation data such as parameter information set in the music device is held. Furthermore, when the device is connected to the music LAN 30, connection information for constructing a logical path of the music LAN 30 is also stored. When the disconnected music device is connected again, the dummy port is returned to the original operation state based on the held connection information, and the operation data is transferred to the device to restore the original music device. Return to the operating state.

  Next, FIG. 2 shows a screen of the arrange window 40 displayed when recording or reproducing in the music processing apparatus 1. In the arrange window 40 shown in FIG. 2, a project file having a file name “MyMusic” is displayed. The project file is a file for storing data including all data for one song in the music processing apparatus 1, and the project file is stored in the hard disk 3a or the flash memory 3b in the personal computer PC of the music processing apparatus 1 shown in FIG. Stored in such a storage device. The music processing apparatus 1 loads the project file into the work memory area of the RAM 4 of the personal computer PC by the OS and DAW 2 processing executed by the CPU 5, or conversely, the stored contents of the work memory area as the file are stored in the hard disk 3a, It can be saved in a storage device such as the flash memory 3b. FIG. 4 shows the data structure of the project file. As shown, the project file 43 includes a header, audio track data (waveform data and management data for a plurality of tracks), audio mixer data (parameters for a plurality of channels). ), MIDI track data (sequence data for multiple tracks), MIDI mixer data (parameters for multiple channels), software sound source data (started software sound source parameters), hardware sound source data (registered in the sound source rack) Hard sound source parameters), soft effector data (activated soft effector parameters), hard effector data (inserted hard effector parameters), TG (sound source) table & EF (effector) Table, music LAN data, It is constructed from the data. In the header, information such as the file name, creation date and size is managed. The TG table is composed of device data including the device name of each of the music devices 31 to 34 that are hardware sound sources externally connected to the music processing device 1, the association with the editor, the number of ports, the association with the ports, and the like. The EF table includes the device names of each of the music devices 31 to 34 that are hardware effectors externally connected to the music processing device 1, the association with the editor, the number of ports, the association with the ports, and the like. It is the table which consists of device data which includes. The music LAN data is connection information indicating logical connections between the music devices 31 to 33 and the music processing apparatus 1 connected via the music LAN, and other data in the project file 43 is the user. This is an area for storing information such as a device data library made up of device data for a plurality of devices set manually by.

  The arrange window 40 includes a track type column 40b for displaying the track type (Type), a track name column 40c for displaying the track name (TrackName), and an output destination column 40d for displaying the output destination of the track. An edit button 40a is provided for each track, and is displayed at the head of each track for setting each track. In the track type column 40b, an audio track is indicated by “A”, and a MIDI track is indicated by “M”. In the project file “MyMusic”, the output destination of the audio track with the track name “Piano 1” is bus 8 (bus 8), and the output destination of the audio track with the track name “Guitar” is also bus 8 (bus 8). The output destination of the audio track having the track name “Sax” is the bus 12 (bus 12). Furthermore, the output destination of the MIDI track whose track name is “Drums” is the first port of the hard sound source whose sound source name is “MOTIE FS7”, and the output destination of the MIDI track whose track name is “Bass” is the sound source name “vB-5” And the output destination of the MIDI track whose track name is “Synth ES” is the third port of the hardware sound source whose sound source name is “MOTIE FS7”. Furthermore, the time series events of each track are displayed on the event display unit 40e so as to correspond to each track. Then, by operating the displayed operation button 41 by clicking with the mouse, it is possible to record on the track selected in the arrange window 40 according to the operated operation button or to play back the selected track. it can.

  Next, FIG. 3 shows a rack screen 42 of a sound source rack that is a rack object to be registered when using a plug-in software sound source and an externally connected hardware sound source. As shown in the rack screen 42, the sound source rack is provided with a mute button 42c, an edit button 42d, and a sound source name column 42b. For example, in the sound source rack whose sound source rack name 42a is “custom 1” shown in FIG. Is mounted. Here, when the software sound source with the sound source name “vB-5” is registered in the sound source rack, the software sound source program of the corresponding instrument plug-in software is executed, and the software sound source “vB-5” is executed from the music processing apparatus 1. A MIDI output port for supplying a MIDI event to the music processing apparatus 1 and an audio input port for outputting the musical sound generated in the software sound source “vB-5” to the music processing apparatus 1 are created. In this case, the name “vB-5” which is the sound source name is automatically given to the MIDI output port and the audio input port. For example, in the MIDI track, the output destination of the MIDI event can be designated by the name “vB-5” of the software sound source. Further, by turning on the mute button 42c corresponding to the software sound source “vB-5” in the sound source rack, the audio signal supplied from the software sound source “vB-5” via the audio input port can be muted. Also, by clicking the edit button 42d, the editing screen of the software sound source “vB-5” is opened, and the tone color parameters and sound source parameters of the software sound source “vB-5” can be edited.

  Next, when the mixer screen is opened, a mixer screen with an audio channel strip added corresponding to the software sound source “vB-5” is displayed. In the added audio channel strip, the input and output routing of the audio channel can be set, and a soft effector or a hard effector can be inserted into the audio channel. The audio channel strip is provided with mute, pan and fader controls and a level meter. The pop-up menu that opens when setting the input and output routing of audio channels is easy because the input port and output port that can be selected are displayed with the sound source name, track name, and bus name. Routing settings can be made.

  Also, if the MIDI sound source of the sound source name “MOTIE FS7” is a hardware sound source externally connected to the music processing device 1, the hardware sound source “MOTIE FS7” is connected to the music processing device 1 externally. The music processing apparatus 1 inquires of the sound source “MOTIE FS7”, generates device data of the sound source section of the hardware sound source “MOTIE FS7”, and stores it in the device data library. When the hardware sound source device data is selected from the library and registered for use, the hardware sound source device data is moved from the device data library to the TG table, and the hardware sound source “MOTIE FS7” is registered in the sound source rack. become able to. Thereafter, when the hardware sound source is registered in the sound source rack, a mixer screen to which an audio channel strip is added corresponding to the hardware sound source is displayed on the mixer screen. For hardware sound sources registered in the sound source rack, the port names are replaced based on the corresponding device data in the TG table, so the names of the MIDI output ports and audio input ports corresponding to the hardware sound source “MOTIE FS7” are The name of the sound source "MOTIE FS7" will be changed. Furthermore, since the hardware sound source registered in the sound source rack is associated with the editor based on the corresponding device data in the TG table, the edit button 42d corresponding to the hard sound source “MOTIE FS7” of the sound source rack is clicked. By doing this, the editor editing screen of the hardware sound source “MOTIE FS7” is opened, and the tone parameters and sound source parameters of the hardware sound source “MOTIE FS7” can be edited.

Next, FIG. 5 shows an example of the mixer screen 44. In the mixer screen 44 shown in FIG. 5, in each audio channel strip, input and output routing of the audio channel and setting of insertion of a soft effector or a hardware effector into the audio channel can be performed. The audio channel strip is provided with a mute 44e, pan 44f, fader 44g controls and a level meter 44h. In the pop-up menu that opens when setting the input and output routing of audio channels, you can select from the menu of input ports or output ports to which sound source names, track names, and bus names are assigned, so routing is easy. Can be set.
In the second audio channel strip from the left on the mixer screen 44, the input 44a is set to “MOTIE FS7” and the output 44b is set to “A Tr 3”. In other words, in this audio channel, the audio signal (musical sound) generated by the hard sound source “MOTIE FS7” is input to the audio channel from the audio input port set for the hard sound source “MOTIE FS7”, and from that audio channel. It can be seen that is set to be output to the third audio track (A Tr 3). Further, an effector 44c having an effector name “SPX1500 comp”, that is, a compressor is inserted in this audio channel. The compressor is an effector that reduces the volume at a set ratio when the volume exceeds a preset threshold. The effect parameters of the effector can be edited by opening the effector editing screen by operating the edit button 44d displayed corresponding to the effector.

Here, the insertion point at which the effector 44c is inserted in the audio channel is shown in FIG. When the effector 44c is inserted, the effector 44c is inserted at an insertion point 44c ′ between the input 44a and the fader 44g. That is, the effect is applied to the audio signal input from the input 44a by the effector 44c, and the result is output to the fader 44g. The audio signal adjusted to a predetermined level by the fader 44g is output to the output 44b via the mute 44e. Therefore, it can be muted by operating the button of the mute 44e provided in the audio channel strip. The output level in the audio channel is displayed on the level meter 44h.
As described above, “use setting” in the present invention means that a sound source is registered in a sound source rack, and that an effector is inserted in an audio channel strip. Further, “use registration” in the present invention means that the hardware sound source is registered in the TG table, and the hardware effector is registered in the EF table.

Next, FIG. 7 shows a data structure of a TG table for managing hardware sound source information. In the TG table, device data of a music device (hard sound source) manually added by a user can be registered, and device data of a music device (hard sound source) registered in the TG library can be registered.
As shown in FIG. 7, the TG table includes management information such as the data size of the TG table and the number of devices to be managed, and device 1 data, device 2 data, device 3 data, etc., which are device data of each music device. Has been. The data structure of the device data of each music device is the same. In FIG. 7, the data structure of the device 3 data is shown expanded. As shown in FIG. 7, the device 3 data includes management information such as the data size of the device 3 data and the number of I / O devices, a device name or device ID (identification) “MF100008”, which is “MOTIE # FS”, and “MF100008”. Control that identifies the device serial number, editor mapping information indicating the editor program or instance specified as “ML Editor-1”, and control port specified as “ML # I / O # aS2” Port information, port information indicating ports for communication of MIDI events and audio signals, other information, and flags. Here, the device serial number is information for distinguishing each music device when the same type of music device is externally connected to the music processing apparatus 1, and the editor association information edits the parameters of the music device. This is link information that designates an editor (remote control software), and is information that can be associated with one instance of them even when a plurality of editors of the same type are activated. The control port information is information indicating a port when the remote control unit (started remote control software) 14 communicates with the music device by serial communication. Each parameter and various parameters of the music device are transmitted via the control port. Settings are made. The control port is not limited to a serial port, but may be a MIDI input / output port. Further, the flag indicates information on whether or not the music device is being used, and information on whether the music device is in an operating state or a dummy state. The other information is information on delay characteristics and gain characteristics for each I / O device.

  The port information includes management information and information for each port, and the data structure of the port information is developed in FIG. As shown in FIG. 7, the port information includes management information for managing the data size of the port information, the number of MIDI output ports, the number of audio input ports, the channel configuration of the audio channel, etc., information on the I / O device, and I / O. It consists of port information and information for each port consisting of delay and return gain. In the example shown in FIG. 7, information for specifying one MIDI output port of the music processing device 1 and six audio input ports corresponding to 5.1 channels is set for communication with “MOTIE FS”. . The logical I / O port “3M1” of the music LAN I / O device “ML # I / O1” is designated as the MIDI output port (MIDI # out1), and there are no other parameters for this output port. As an audio input port for 6 channels (Audio # inL, Audio # inR, Audio # inC, Audio # inLS, Audio # inRS, Audio # inLE), 6 of the music LAN I / O device “ML # I / O1” Two logical I / O ports “2A1”, “2A2”, “2A3”, “2A4”, “2A5”, “2A6” are specified, and a delay of 0.8 ms is set as a parameter of each audio input port. A return gain of 2 dB is set. “Delay” is a delay time from when a MIDI event is supplied to “MOTIE # FS” until the corresponding audio signal is output. DAW2 supplies “MOTIE FS” to compensate for the delay. It has a function to output a MIDI event that should occur earlier than the time. The I / O port “3M1” is a port logically formed in the music processing apparatus 1 as a MIDI output port for outputting a MIDI event to a music device connected to the music LAN, and “3M1”. Is read as a MIDI output port. The I / O ports “2A1” to “2A6” are ports prepared for audio input ports, and are recognized as audio input ports when the information of “2A1” to “2A6” is read. For the hardware effector, an EF table similar to the TG table is created and managed.

  Next, an external sound source registration screen for registering device data of a music device (hard sound source) in the TG table is shown in FIG. In the external sound source registration screen 46 shown in FIG. 8, an “add external musical instrument” button 46a and a “library” button 46b are provided. When the user manually adds and registers a hardware sound source, an item for setting necessary information of the hardware sound source is added to the TG table by an additional registration dialog that is opened by operating the “add external instrument” button 46a. Thus, the added item can be manually registered individually. When registering device data of a music device (hard sound source) from a library (device data library) in the TG table, the “library” button 46b is operated. As a result, a selection menu for selecting device data of the music device (hard sound source) registered in the library is opened, and the desired music device (hard sound source) can be selected and registered in the TG table. Note that device data of music devices (hard sound sources) registered as user favorites in the library and music automatically registered when music devices (hard sound sources) are connected to the music processing apparatus 1 via the music LAN. The device data of the device (hard sound source) is registered. As described above, when the registration process to the TG table is performed, the device data of the registered music device (hard sound source) is added to the list of music devices on the external sound source registration screen and displayed.

  In the list of the external sound source registration screen, as the device data of the music device (hard sound source) registered in the TG table, the name of the music device, the I / O device and the I / O port connected to the music device (Information specifying the port), information indicating the editor controlling the music device and its control port, and a flag indicating whether or not the music device is being used. In the external sound source registration screen 46 shown in FIG. 8, hardware sound sources “TRITOTT”, “PHONTOM”, and “MOTIE # FS” are registered as the device names of music devices. “TOTT # Editor” of “Control / TOTT # Editor (ML # I / O1 # aS1)” displayed after the hardware sound source name “TRITOTT” is information to specify the software (editor) for remote control. The software is activated when the hardware sound source “TRITOTT” is remotely controlled to edit or set parameters. “ML # I / O1 # aS1” means a serial port (S1) in an asynchronous channel (a) of an I / O device (ML # I / O1) of a music LAN (for example, mLAN (registered trademark)). ing. That is, the hardware sound source “TRITOTT” is connected to the music LAN 30. The same applies to the “control / MOTIE # Editor (ML # I / O1 # aS2)” displayed after the hardware sound source name “MOTIE # FS”, and the software “MOTIE #” specified for remote control is used. “Editor” is activated when the hardware sound source “MOTIE # FS” is remotely controlled to edit or set parameters. “ML # I / O1 # aS2” means the serial port (S2) in the asynchronous channel (a) of the mLAN (registered trademark) I / O device (ML # I / O1). That is, the hardware sound source “MOTIE # FS” is also connected to the music LAN 30 of mLAN (registered trademark). As for the hardware effect device, a similar external effect device registration screen for registering the device data of the music device (hard effect device) is prepared in the EF table, and the music device (hard effect device) is operated in the same manner. Device data is registered in the EF table.

  In the external sound source registration screen 46 shown in FIG. 8, the layer of the hardware sound source “MOTIE # FS” is expanded and displayed, and in the next lower layer, the configuration of the MIDII / O port and the audio I / O port are displayed. The configuration is shown. As shown in the figure, one MIDI output port (MIDI # out1) and six audio input ports (Audio # inL, Audio # inR, Audio # inC, Audio # inLS) for the hardware sound source “MOTIE # FS” , Audio # inRS, Audio # inLE). In these port items, I / O devices and I / O ports are displayed based on the device data of the hardware sound source “MOTIE # FS” in the TG table shown in FIG. In response to an operation on the external sound source registration screen 46, the device data of the music device stored in the TG table is edited. The hardware sound source in which the device data corresponding to the TG table is registered can be displayed and selected from the TG selection menu in the sound source rack. The hardware sound source in the dummy state is displayed in gray in the TG selection menu in the sound source rack so that it cannot be selected. When selected and registered in the TG selection menu of the sound source rack, “×” is displayed in the use column on the external sound source registration screen 46, and the flag indicating that the flag of the TG table is used. Be changed. Further, the name of the hardware sound source is deleted from the TG selection menu in the sound source rack and is not displayed. As a result, two hardware sound sources cannot be registered in the sound source rack. Although the software sound source is managed separately from the TG table, a plurality of software sound sources are displayed on the TG selection menu and can be registered even if they are registered once.

  Next, FIG. 9 shows a screen of an additional registration dialog 47 that is opened by operating the “add external instrument” button 46a. In the additional registration dialog 47 shown in FIG. 9, the name “PHONTOM” of the hardware sound source to be added is entered in the instrument name input field. Furthermore, “1” is input to the input field of the MIDI output port (MIDI # out) and “4” is input to the input field of the audio input port (Audio # in) as the number of ports of the hardware sound source “PHONTOM”. Yes. In addition, the name of the software for remote control can be input in the “control” input field, and the port used for remote control can be input in the “port” input field. When adding the hardware sound source device data to the TG table based on the data input in each input field, the “OK” button is operated. As a result, the device data of the hardware sound source “PHONTOM” is added to the TG table, and the corresponding item is displayed on the external sound source registration screen 46. At this point, items such as port information indicating MIDI / audio input / output ports are not set yet and are blank, and the user must manually set each item sequentially. If not added, the “Cancel” button may be operated.

  Here, the library (device data library) will be described. The library includes a TG library in which a hardware sound source is registered and an EF library in which a hardware effector is registered. In the TG library, device data of a music device (hard sound source) registered as a user's favorite, or a device of music device (hard sound source) automatically registered when connected to the music processing apparatus 1 via the music LAN Data is registered. The user can select device data of a desired hardware sound source from the TG library and register it in the TG table. Further, not only the user's disconnection operation, but also when the music device (hard sound source) is disconnected from the music processing apparatus 1 due to an erroneous operation or accident, the device data of the music device (hard sound source) is deleted from the TG library. The In this case, if a hardware sound source registered in the sound source rack is disconnected from the music processing device 1, the registration of the music device (hard sound source) is in a “dummy” state, but the parameters of the music device (hard sound source) Are stored in a parameter memory (a work memory area on the RAM 4 of the personal computer PC shown in FIG. 28, a predetermined work area on the hard disk 3a or the flash memory 3b, etc.) in the music processing apparatus 1. When the hardware sound source is connected to the music processing apparatus 1 again, the stored setting data is transferred to the hardware sound source and automatically set, and the dummy state is released and the operation state is activated. The same processing is performed for the EF library, and the device data of the music device (hard effect device) in the EF table can be registered in the EF table. The music device registered in the EF table is displayed on the EF selection menu for selecting an effector to be inserted in the audio channel strip and can be selected.

  Also, in the EF library, device data of music devices (hard effect devices) registered as user favorites, and music devices (hard effect devices) automatically registered when connected to a music processing device via a music LAN. ) Device data is registered. The user can select device data of a desired hardware effector from the EF library and register it in the EF table. The hardware effectors registered in the EF table are displayed in the EF selection menu and can be inserted into a desired audio channel strip. In addition, the music device (hard effector) is not deleted from the EF library when the music device (hardware effector) is disconnected from the music processing apparatus 1 due to an erroneous operation or an accident. . In this case, if the hardware effector inserted in the audio channel strip is disconnected from the music processing apparatus 1, the music device (hardware effector) is in the “dummy” state, but the music device (hardware effector) ) Setting data such as parameters is held in a parameter memory (a work memory area on the RAM 4 of the personal computer PC shown in FIG. 28, a predetermined work area on the hard disk 3a or the flash memory 3b, etc.) in the music processing apparatus 1. . Then, when the hardware effector is connected to the music processing apparatus 1 again, the stored setting data is transferred to the hardware effector and automatically set, and the dummy state is released and the operation state is activated.

Next, FIG. 10 shows a flowchart of the “add” button operation event process activated when the “add external instrument” button 46a is operated on the external sound source registration screen shown in FIG.
When the “add” button operation event process is activated, an additional registration dialog shown in FIG. 9 is opened and displayed in step S10. Next, in step S11, input to the instrument name input field, control input field, MIDI output port (MIDI # out) input field, and audio input port (Audio # in) input field is accepted. Next, in step S12, it is determined whether or not there is a registration instruction. Here, when the “OK” button is operated, it is determined that there is an instruction for registration, and in step S13, the device data of the hardware sound source (instrument) is additionally registered in the TG table shown in FIG. The button operation event process ends. If the “Cancel” button is operated and it is determined in step S12 that there is no instruction for registration, the “add” button operation event process is terminated.
A port storage area for storing port information of the music device (hard sound source) added by the “add” button operation event process is also created, but designation of individual ports in the port information is not input, The I / O port column for display is blank. Therefore, the user must sequentially click on the blank I / O port column and sequentially set the port designation. At this point, the added music device (hardware sound source) is not yet registered in the sound source rack. If the music device is a hardware effect device, it is displayed in the EF selection menu in the audio channel strip when it is registered in the EF table, but the individual port designation has not yet been set, so insert it. Also can not connect the insertion point.

In a state where the DAW 2 is activated in the personal computer PC and the personal computer PC functions as the music processing apparatus 1, screen operation by the operation element 8 such as a mouse and connection of external devices in the interface unit 9 (including various music I / O 25). An operation event or a processing command is generated in response to detection or the like, and a processing routine corresponding to the event or command that constitutes a part of the DAW 2 is appropriately started, so that processing corresponding to screen operation or connection detection of an external device is performed. Done. The main event response processing routine and command processing routine will be described below. First, FIG. 12 shows a flowchart of click event processing that is started when an I / O port column of a desired music device (instrument) on the external sound source registration screen or TG table is clicked.
Clicking on the I / O port column of the desired music device (musical instrument) on the external sound source registration screen starts the click event processing, and the user clicked on the I / O device port of the music signal processing device 1 in step S20. A menu in which the types corresponding to the field and the unassigned ports are listed is displayed. Next, an input of a selection operation is accepted in step S21, and it is determined in step S22 whether there is a selection instruction for selecting one displayed on the menu. If it is determined that there is a selection instruction, the process proceeds to step S23, and information specifying the selected port is written in the device data of the device in the TG table. In step S24, it is determined whether the music device (musical instrument) for which the I / O port field is clicked is registered in the sound source rack. If the music device (musical instrument) is registered in the sound source rack, step S25 is performed. Proceed to In step S25, the name of the selected port among the displayed or displayed port names is updated to the port name of the music device (musical instrument). When the process of step S25 is completed, or when it is determined in step S22 that the outside of the menu has been clicked and no selection instruction has been given, the desired port column click event process for the desired instrument is completed. In this way, every time this click event process is executed, one port is designated and set.
If the music device is an effect device, it is displayed on the EF selection menu in the audio channel strip when it is registered in the EF table, and can be selected and inserted. Accordingly, in step S24, it is determined whether “the effector is inserted in any channel strip”. If it has been inserted, in step S25, connection to the port designated as the insertion point is set. Is done. Further, if the music device is an effect device, the “port name” updated in step S25 becomes “effect device name”, and the updated effect device name selects an effect to be inserted into each audio channel of the audio mixer. To be displayed on the “effector selection menu” and the setting unit for setting insertion of the effector into each audio channel.

Next, FIG. 11 shows a flowchart of the TG library store instruction event processing for a desired instrument. This process is started when, for example, a TG library store is selected in a menu displayed by right-clicking the mouse.
When the TG library store instruction event process for a desired instrument is started, the instrument data of the music device (musical instrument) in the TG table corresponds to the music instrument (musical instrument) name in units of music instrument (instrument) in step S30. It is saved as a favorite music device (instrument) in the TG library by name. If the music device is an effect device, when the store instruction for the EF library is given, the data of the music device (effect device) in the EF table is stored in units of the music device (effect device). It is stored as a favorite music device (effect device) in the EF library with a name corresponding to the name of the effect device).

Next, FIG. 13 shows a flowchart of a recall instruction event process for a desired instrument in the TG library. This process is activated when, for example, a TG library recall instruction is selected in a menu displayed by right-clicking the mouse.
When the recall instruction event process for the desired instrument in the TG library is started, the instrument data of the music instrument (instrument) instructed to be recalled in the TG library is read and registered in the TG table in step S40. Next, it is determined whether or not the device data registered in step S41 is device data of a music device (musical instrument) automatically registered in the TG library. If it is determined that the device data of the music device (musical instrument) automatically registered in the TG library, the process proceeds to step S42, and only one music device (musical instrument) automatically registered in the TG library can be registered. Therefore, the music device (musical instrument) registered in the TG library is deleted together with the device data. If it is determined that the device data of the music device (musical instrument) is not automatically registered, the process branches to step S43. The music device (musical instrument) is a music device (musical instrument) manually registered in the TG library by the user. ) And each of its ports may already be in use. Therefore, in step S43, each port in the device data registered in the TG table is associated with each port that currently exists and is not used. Next, the ports that could not be associated in step S44 are deleted. When the process of step S42 or step S44 is completed, the recall instruction event process for the desired instrument in the TG library is terminated.

  Next, FIG. 14 shows a flowchart of a device connection detection event process to the music LAN. The device connection detection event process to the music LAN is activated at predetermined intervals, and when activated, device information such as the device ID of the music device detected to be newly connected is acquired in step S50, and the music It is determined whether the device is a hardware sound source or a hardware effector. Next, it is determined whether or not the music device detected in step S51 conforms to the plug and play function functioning in the music processing apparatus 1. Here, if it is determined that it is not compliant, the automatic connection cannot be established, so the device connection detection event process to the music LAN ends. On the other hand, if it is determined that it is compliant, the process proceeds to step S52 to automatically connect the music device detected under the control of the personal computer (PC) on which the music processing device 1 is realized to the music processing device 1. Is called. However, if the music device is a device having an mLAN interface, it is logically connected by the mLAN function when the device is connected. In this case, the process of step S52 is performed. There is no need.

  Next, the remote control unit 14 inquires the music device detected in step S53 through the serial communication path, and acquires the device name, MIDI port and device data of the audio port and various data of the I / O port. Create device data. Then, association with a music device whose display is currently in a dummy state is performed. In step S55, it is determined whether or not the detected music device can be associated with any of the music devices in the dummy state. If it is determined that the music device is in a dummy state, the parameters of the music device in the dummy state are set in the parameter memory (the work memory area on the RAM 4 of the personal computer PC shown in FIG. A predetermined work area on the hard disk 3a or the flash memory 3b) is read to restore the setting. Further, the display of the music device is changed from the dummy state to the operating state (normal state). As a result, the remote control can be performed by the editor corresponding to the music device, and the parameters can be edited. Regardless of whether it is in operation or in a dummy state, the music device (hard sound source) registered in the sound source rack and the music device (hard effect device) inserted in the audio channel strip are associated with the editor. Then, the corresponding editor is activated, and parameters for controlling the operation of these music devices are stored in the music processing apparatus 1 (such as a work memory area on the RAM 4 of the personal computer PC shown in FIG. 28). Then, when switching from the dummy state to the operating state (normal state), the above parameters in the music processing device and the parameters in the music device are automatically synchronized to start remote control. .

  Next, the display of the music device or the set port set in the TG table or EF table that has been grayed out in step S57 is restored. Here, the music device that is set to be used but is not currently connected is in the dummy state. Then, if the music device is a hardware sound source, it is registered in the sound source rack, so if it is in a dummy state, it is displayed in gray in the sound source rack, so this gray display is also restored. If the music device is a hardware effector, since it is inserted in the audio channel, the effector display in the audio channel strip is also displayed in gray, so this gray display is also restored. Further, if it is determined in step S55 that the detected music device does not correspond to any music device in the dummy state, it is not set to be used and is newly connected. Since it is a music device, the process branches to step S58, and if the detected music device is a hardware sound source, the device data is stored in the TG library. If the detected music device is a hardware effector, the device data is stored in the EF library. When the process of step S57 or step S58 ends, the device connection detection event process to the music LAN ends. As described above, the automatic registration of the music device whose connection to the music LAN is detected to the TG library or the EF library is performed only when the music device cannot be associated with the music device in the dummy state. It is like that.

Next, a flowchart of logical connection change event processing in the music LAN is shown in FIG. This process is started when a connection change event occurs on the logical connection screen for setting the logical connection between devices in the music LAN 30.
First, an example of the logical connection screen 48 in the music LAN 30 is shown in FIG. In the logical connection screen 48, the PC 48a displayed on the left side is the personal computer shown in FIG. “MOTIE # FS” 48b and “TRITOTT” 48c displayed on the upper side are hardware sound sources externally connected to the music processing apparatus 1 via the music LAN 30, and “SPXX” 48d and “TRIXX” displayed on the right side. SPXY "48e is a hardware effector externally connected to the music processing apparatus via the music LAN 30. A communication path (connection) indicated by a broken line connecting the PC 48a and the hardware sound sources 48b and 48c and between the PC 48a and the hardware effectors 48d and 48e is a bidirectional communication path for MIDI, and is a solid line. The communication path (connection) shown is a two-way audio communication path. The pentagonal mark displayed on the nuclear communication path indicates a communication line in each direction of the communication path, and the number in the mark indicates the number of lines. A line indicated by a mark 48h with a pointed tip directed to the PC 48a is an input line from each device to the PC, and a pointed tip is directed to the hardware sound source 48b, 48c or the hardware effector 48d, 48e. A line indicated by 48i is an output line from the PC to each device. For example, one MIDI input line and one output line are set between the PC 48a and the hardware sound source 48b, and six audio input lines are set. In this case, the PC 48a is provided with one MIDI input port and one MIDI output port correspondingly in software, and further provided with six audio input ports in software.

  The number of lines of each line can be set to an arbitrary number by a pop-up menu displayed by clicking the mark of the line. For example, when the mark of the audio input line for the hardware sound source 48b is clicked, the number of lines can be changed from “6” to an arbitrary number of lines. When the number is changed, the number in the mark is changed to the changed number. Here, by operating the execution button 48f, the music LAN setting parameters of the PC 48a and each music device are respectively set according to the set number of lines. Controlled and logical connection of music LAN is set. When the number of lines between the PC 48a and the music device is increased, a port for new connection is generated in the PC 48a accordingly, and when the number of lines is decreased, the corresponding connection port of the PC 48a disappears. Further, when an operation for reducing the number of lines is performed, if the line to be reduced is in use, it cannot be reduced by operating the execution button 48f. Note that the logical connection screen 48 is closed by operating the “close” button 48g.

  The logical connection change event process is started when the execution button 48f is operated on the logical connection screen 48 shown in FIG. 27. If the music device whose logical connection is changed in step S60 is a hardware sound source, it is registered in the sound source rack. In the case of a hardware effector, it is determined whether it is inserted into an audio channel and used. If it is determined that the music device is not registered / inserted, the process branches to step S63 and the TG library (for a hardware sound source) or EF library (for a hardware effector) of the music device. The data port information is updated to reflect the state of the logical connection changed by the connection change event.

  If it is determined in step S60 that the logical connection of the registered / inserted music device has been changed, the process proceeds to step S61, and the TG table (in the case of a hardware sound source) or EF table (hard effect) of the music device. Device data) is updated to reflect the state of the logical connection changed by the connection change event. Next, in step S62, each display is updated corresponding to the change of the logical connection. Specifically, among the already connected ports, the ports that no longer exist due to the change of the logical connection are made dummy and displayed in gray. Further, for unconnected ports, control is performed so that only ports that currently exist are displayed in the “port selection menu”. If the dummy port is restored by changing the logical connection, the display is returned from the gray display to the normal display. When the process of step S62 or step S63 ends, the logical connection change event process in the music LAN ends.

Next, FIG. 16 shows a flowchart of a disconnection event process for a device from the music LAN. This event processing is not limited to when a music device is disconnected on the logical connection screen of the music LAN 30, but when a music device connected so far is physically or logically disconnected from the music LAN 30 for some reason. Also activated.
When the disconnection event processing is started, if the music device disconnected from the music LAN 30 in step 70 is a hardware sound source, whether or not it is registered and used in the sound source rack is used. It is determined whether it is inserted and used. Here, if it is determined that the music device is not registered / inserted, the process branches to step S73 and the TG library (in the case of a hardware sound source) or EF library (in the case of a hardware effector) of the music device. The device data of the disconnected music device is deleted.

  If it is determined in step S70 that the logical connection of the registered / inserted music device is disconnected, the process proceeds to step S71, and the TG table (in the case of a hardware sound source) or EF table (hard effector) of the device. Device data of the disconnected music device is dummyized, and the corresponding setting data is stored in the parameter memory (the work memory area on the RAM 4 of the personal computer PC shown in FIG. 28, the hard disk 3a and the flash memory). 3b). Next, in step S72, all displays related to the dummy device data in the music processing apparatus 1 are dummyized. Specifically, in the sound source rack, the audio channel strip, and the like, the display of the device name of the music device that is performed based on the device data is made dummy and displayed in gray. Further, control is performed so that the data of the music device is not displayed on the various selection menus. When the process of step S72 or step S73 ends, the disconnection event process of the device from the music LAN ends. Note that the port to which the disconnected music device of the music processing device 1 is connected automatically disappears when the music device is disconnected, so the port selection menu displayed in the audio channel strip or the like is Even if you do not control anything, it will not be displayed.

Next, FIG. 17 shows a flowchart of the sound source name field click event process activated when a desired sound source name field in the sound source rack is clicked.
When the sound source name column click event process is started, a TG selection menu is displayed in step S80. In this TG selection menu, hardware sound sources registered in the TG table and soft sound sources plugged in are displayed. However, sound sources already registered in the sound source rack are grayed out or not displayed and cannot be selected. Is done. Next, in step S81, user input in the TG selection menu is accepted, and in step S82, it is determined whether or not a selection instruction is input in the TG selection menu. If it is determined that a selection instruction has been input, the process proceeds to step S83, and it is determined whether or not a sound source has been selected in the clicked sound source name field before the selection instruction (before change). If it is determined that any sound source has been selected before the instruction (before change), the process branches to step S84 to perform processing for returning the sound source before change to the state before registering the sound source in the sound source rack. When the process of step S84 is completed, or when it is determined in step S83 that the sound source has not been selected before the instruction (before the change), the process proceeds to step S85 and is displayed on the TG selection menu by inputting the selection instruction. It is determined whether or not any of the selected sound sources has been selected, that is, whether or not a sound source has been selected in the clicked sound source name column after the selection instruction (after change). If it is determined that a sound source is selected in the clicked sound source name field, the process branches to step S86 to perform processing for registering the changed sound source in the sound source rack. Then, the processing in step S86 is completed, or “−” displayed in the TG selection menu is instructed to be selected, and an instruction to remove the sound source is given. In step S85, the sound source is selected in the clicked sound source name column. If it is determined that there is not, the sound source name column click event process of the desired rack is completed. On the other hand, if it is determined in step S82 that an area outside the TG selection menu is clicked and the selection instruction is not input, the sound source name column click event process is stopped and the process ends.

Next, FIG. 18 shows a flowchart of the processing for returning the sound source before change executed in step S84 in the sound source name column click event processing of the desired rack to the state before registration in the sound source rack.
When the process of returning to the previous state is started, the sound source name (instrument name) is deleted from the corresponding column of the sound source rack in step S90. Next, in step S91, it is determined whether the type of the sound source is a hard sound source (H sound source) or a soft sound source (S sound source). Here, when it is determined that the sound source is a hardware sound source, the process proceeds to step S92 to connect to the hardware sound source by the device data of the hardware sound source (instrument) among the port names displayed or displayed in the music processing apparatus 1. Change the name of the port specified as the port back to the original name. Further, if the editor association is set in the device data, the activated editor is terminated, and on the RAM 4 of the personal computer PC shown in FIG. 28 corresponding to the hardware sound source (musical instrument) in the music processing apparatus 1. The parameter storage area in the work memory area is released. In step S93, the instrument is changed to “unused”. As a result, “x” in the use column in the external sound source registration screen 46 is removed. If it is determined in step S91 that the sound source is a software sound source, the process branches to step S94 to disconnect all connected ports in the software sound source (instrument) and simultaneously delete the port name. Next, in step S95, the program of the software sound source (instrument) is stopped, so that the corresponding port disappears, and in the work memory area on the RAM 4 of the personal computer PC shown in FIG. 28 corresponding to this port. The parameter storage area secured in the above is released. When the process of step S93 or step S95 ends, the process of returning to the previous state ends, and the process returns to step S85 of the sound source name column click event process of the desired rack.

Next, FIG. 19 shows a flowchart of the process of placing the changed sound source into the sound source rack executed in step S86 in the sound source name column click event process of the desired rack.
When the process of entering the sound source rack is started, the sound source name (instrument name) is displayed in the corresponding field of the sound source rack in step S100. Next, in step S101, it is determined whether the type of the sound source is a hard sound source or a soft sound source. If it is determined that the sound source is a hardware sound source, the process proceeds to step S102, and the connection to the hardware sound source is performed by the device data of the hardware sound source (instrument) among the port names displayed or displayed in the music processing apparatus 1. The name of the port designated as the port is updated to the name of the sound source name (instrument name) based on the device data. If the editor data is associated with the device data, the editor program is started, and a parameter storage area for remotely controlling the hardware sound source (instrument) is stored on the RAM 4 of the personal computer PC shown in FIG. Allocate in the work memory area. Next, in step S103, the instrument is changed to “in use”. As a result, “x” is displayed in the use column on the external sound source registration screen 46. If it is determined in step S101 that the sound source is a software sound source, the program branches to step S104 to start the software sound source (instrument) program, and a storage area for storing the parameters of the software sound source is shown in FIG. A port is secured in the work memory area on the RAM 4 of the personal computer PC and connected to the software sound source. Next, the port generated in step S105 is made connectable, and a port name that is the name of the software sound source (instrument) is given. When the process of step S103 or step S105 is completed, the process of entering the sound source rack is completed, and the process returns to the sound source name column click event process of the desired rack.

Next, a flowchart of the port selection operation event process is shown in FIG. This process is activated when a port column (40d, 44a, 44b, etc.) or a “port selection” in the menu is clicked in a MIDI track, MIDI mixer, audio track, audio mixer, or the like.
When the port selection operation event process is started, a port selection menu is displayed in step S110, and a user input is accepted in step S111. The port name for connection to the sound source and the port name for connection to the effector displayed in the port name selection menu are the sound source name for the sound source registered in the sound source rack and also registered in the EF table. The effector name is given to the effector so that it can be selected intuitively. Then, it is determined whether or not the input accepted in step S112 is a port selection instruction input. If it is determined that a port selection instruction is input, the process proceeds to step S113 to connect the selected port to the MIDI / audio track or MIDI / audio channel as the element. Since one port is connected to only one element, the port selection menu is updated so that a port that has already been selected is not displayed. When the process of step S113 ends, the port selection operation event process ends. If it is determined in step S112 that an area outside the port selection menu is clicked and it is determined that the selection instruction is not input, the port selection operation event process is stopped and the process ends.

Next, FIG. 21 shows a flowchart of the effector name column click event process activated when the effector name column (44c, etc.) of the desired audio channel strip in the audio mixer is clicked.
When the effector name column click event process is started, an EF selection menu is displayed in step S120. In this EF selection menu, hardware effectors registered in the EF table and plugged-in software effectors are displayed, but effectors already inserted in the audio channel are grayed out or not displayed. Cannot be selected. Next, in step S121, user input in the EF selection menu is accepted, and in step S122, it is determined whether or not a selection instruction is input in the EF selection menu. If it is determined that a selection instruction has been input, the process proceeds to step S123, where it is determined whether an effector has been selected before the instruction (before change) in the clicked effector name field. If it is determined that any effector has been selected before the instruction (before the change), the process branches to step S124 to perform a process for returning the effector before the change to the state before being inserted into the audio channel. Is called. When the process of step S124 is completed, or when it is determined in step S123 that the effector has not been selected before the instruction (before the change), the process proceeds to step S125 and is displayed on the EF selection menu by inputting the selection instruction. It is determined whether or not any of the effectors that have been selected is selected, that is, whether or not an effector has been selected in the effector name column clicked after the instruction (after change). Here, if it is determined that an effector is selected in the clicked effector name column, the process branches to step S126 to perform processing for inserting the changed effector into the audio channel. Then, the processing of step S126 ends, or “−” displayed in the EF selection menu is instructed to be instructed to remove the effector, and an effector is displayed in the effector name column clicked in step S125. If it is determined that the audio mixer is not selected, the effect event name column click event process of the desired channel of the audio mixer ends. If it is determined in step S122 that an area outside the EF selection menu is clicked and it is determined that the selection instruction is not input, the effector name column click event process is stopped, and this process ends.

Next, FIG. 22 shows a flowchart of processing for returning to the state before inserting the pre-change effector executed in step S124 in the effector name column click event processing of the desired channel of the audio mixer.
When the process of returning to the previous state is started, the effector name is deleted from the field of the audio channel in step S130. Next, in step S131, the type of the effector, that is, a hard effector (H effector) or a soft effector (S effector) is determined. If it is determined that the hardware effector is selected, the process proceeds to step S132, where the connection to the input / output port designated by the device data of the hardware effector is released, and the insertion connection release process through the insertion point is performed. Further, if the editor association is set in the device data, the activated editor is terminated, and the parameter storage area of the hardware effector in the music processing apparatus 1 is released. Next, in step S133, the effector is changed to “unused”. If it is determined in step S131 that the sound source is a soft sound source, the process branches to step S134, and an insertion connection release process for releasing the port of the soft effector from the insertion point and passing through the insertion point is performed. Next, in step S135, the program of the software effector is stopped, so that the corresponding port disappears and the reserved parameter storage area is released. When the process of step S133 or step S135 is completed, the process for returning to the previous state is completed, and the process returns to step S125 of the effector name column click event process of the desired channel of the audio mixer.

Next, FIG. 23 shows a flowchart of the process of inserting the changed effector executed in step S126 in the effector name column click event process of the desired channel of the audio mixer into the ch strip.
When the process of inserting into the ch strip is started, the effector name is displayed in the corresponding column of the audio channel in step S140. Next, in step S141, the type of the effector, that is, whether it is a hard effector or a soft effector is determined. If it is determined as a hardware effector, the process proceeds to step S142, and an audio signal input / output port designated as a connection port with the hardware effector by the device data of the hardware effector is inserted into the audio channel. Insert and connect to the point. Furthermore, if the device data is associated with an editor, the editor program is started, and a parameter storage area for remotely controlling the hardware effector is secured. Next, in step S143, the effector is changed to “in use”. If it is determined in step S141 that it is a soft effector, the program branches to step S144 to start the soft effector program, thereby securing a storage area for storing the parameters of the soft effector. An audio signal input / output port for connecting a soft effector is generated. Next, the port generated in step S145 is made connectable and is inserted and connected to the insertion point in the audio channel. When the process of step S143 or step S145 ends, the process of inserting into the channel ends, and the process returns to the effector name column click event process of the desired channel of the audio mixer.

Next, FIG. 24 shows a flowchart of the project loading process for loading the project file into the music processing apparatus 1.
When a load of a project file is selected from the file menu of the music processing apparatus 1, a project load command is issued, and a project load processing routine is activated accordingly. When the project loading process is started by the routine, the project file stored in the storage device (the hard disk 3a or the flash memory 3b of the personal computer PC shown in FIG. 28) in step S150 is stored in the personal computer PC shown in FIG. The data is read into a work memory area on the RAM 4. The data structure of this project file is as shown in FIG. 4. In step S151, the hardware sound source and the hardware effector connected to the music processing apparatus 1 by the music LAN 30 at that time are detected, and the detected existing devices are detected. Are associated with the music LAN data in the read project file, and the logical connection of the hardware sound source and hardware effector that can be associated is restored. Next, each piece of device data registered in the TG table and EF table in the project file read in step S152 is associated with a music device as a hardware sound source and a hardware effector, and further music processing is performed. Association with the existing input / output ports of the device 1 is performed. Here, for each music device connected to the music LAN 30, the music processing apparatus 1 can identify the device name and ID of the music device by inquiring, so the correspondence between the device data and the music device includes the serial number. It may be performed strictly, or even if the serial numbers are different, those with matching model IDs may be associated with each other. Further, since it is possible to acquire which port is connected to the music device connected to the music LAN 30, the port information of the device data registered in the TG table or the EF table is corrected based on the information. . For fixed ports other than the music LAN 30, it is not possible to confirm the music device connected to the fixed port. Therefore, the association with the music device is unconditionally performed according to the device data of the TG table and the EF table. In this case, there is no guarantee that the music device is connected, but if the music device connected to the port has not been changed since the project file was saved, it can be used without any problem.

  In step S153, an editor associated with each device data registered in the TG table and the EF table is activated. The activated hard sound generator editor uses the hard sound source data in the imported project file as a parameter for remote control, and the hard effector editor uses the data of the hard effector as a parameter for remote control. To do. An editor that uses a fixed control port other than the music LAN 30 is associated with the control port here. In step S154, the parameters are synchronized by confirming with the user and transferring the setting data from each active editor to the associated music device. As described above, for the music device connected to the music LAN 30, the logical path connecting the music processing device 1 and the music device is restored regardless of whether the port is changed or not after the project file is saved, and the parameters are further changed. Restored. In addition, the hardware sound source and the hardware effector that are registered in the TG table and the EF table but cannot be associated due to separation or the like are the hardware sound source or the hardware effect in the TG table or the EF table in step S155. Dummy display (gray display). Next, in step S156, the software modules of the software sound source and the software effector that are plugged in are activated, and the operation state is restored using the data of the read project file. For example, the track data in the read project file is stored in the hard disk 3a of the personal computer PC shown in FIG. 28 or the track data memory provided in the flash memory 3b, and the parameters are the hard disk of the personal computer PC shown in FIG. 3a, flash memory 3b, and parameter memory provided in the RAM 4. Next, normal operation is started in step S157. As a result, the state when the read project is saved is restored, and the project loading process ends.

Next, FIG. 25 shows a flowchart of the project saving process for saving the project file in the music processing apparatus 1.
When saving of a project file is selected from the file menu of the music processing apparatus 1, a project save command is issued, and a project save processing routine is started in response thereto. When the project saving process is started by the routine, the data constituting the project file shown in FIG. 4 is collected from the corresponding modules in the music processing apparatus 1 in step S160. Next, a project file composed of each data collected in step S161 is written and stored in a storage device (such as the hard disk 3a or flash memory 3b of the personal computer PC shown in FIG. 28) in the music processing apparatus 1. Thereby, the project saving process ends.

  Next, a state of remote control by an editor (remote control software) for a music device connected to the music processing apparatus 1 is simply shown in FIG. In FIG. 26, the remote control communication path for connecting the music processing apparatus 1 and the music device is a MIDI communication path, a serial communication path, a music LAN serial communication path, Ethernet, etc. Each connected control port is specified. The editor activated by the music processing apparatus 1 includes a GUI unit 11 that performs an interface with the user using a display and an operator provided in the PC, and performs music processing in accordance with an instruction given from the user via the GUI unit 11. A remote control parameter stored in the device 1 is edited and an R control module for performing remote control of the music device 51 is provided. The music device 51 includes at least a display and an operation provided in the music device 51. A UI unit 51a for interfacing with a user using a child, and an instruction given by the user via the UI unit 51a or a parameter stored in the music device according to remote control from the music control device 1 A control program 51b for editing and controlling the operation of the music device based on the edited parameters It is equipped with a. When the remote control of the music device 51 is started, the parameters for remote control in the music processing apparatus 1 are transferred to the music device 51 by the function of the R control module 50a via the remote control communication path. The control program 51b sets the parameters in the music device based on the data, and the parameters are synchronized between the music processing device 1 and the music device 51.

Thereafter, the R control module is used both when the editor is activated in the music processing apparatus 1 and the parameters of the music device 51 are edited using the GUI 11 and when the parameters are edited using the UI 51a in the music device 51. The parameters 50a and 50b are controlled so that the parameter data of both are synchronized through the remote control communication path. Even when the music device 51 is switched from the dummy state to the operating state, the data in the music processing device 1 and the data of the music device 51 are synchronized by remote control.
As described above, the separated music device is displayed in a dummy display (gray display), but the parameters of the music device in the dummy state can be edited by the control editor in the music processing apparatus 1. Then, when the music device is reconnected, the parameters edited by the control editor in the music processing apparatus 1 as described above are transferred to the reconnected music device and the parameters are synchronized. It becomes like this.

In the above description, the favorite hardware sound source registered in the TG library is registered in the sound source rack by registering in the TG table. However, when the hardware sound source is externally connected, it is registered in the TG table. You may make it do. In addition, since a new hardware sound source is often connected when used, it may be directly registered in the sound source rack when the hardware sound source is externally connected. In the music processing device, the registration mode described above may be selectable and set to any registration mode. These registration modes can also be applied to the hardware effector, and the same registration mode can be applied to the hardware effector.
In addition, although the external device in which disconnection is detected is displayed in a dummy display, the remote control software of the device may be able to edit the parameter even in the case of the dummy display. By doing so, even if the device is not at hand, the parameters can be prepared by the remote control software.
Furthermore, performance event data for driving a sound source is not limited to MIDI event data. Any kind of performance event data can be used in which the tone color of each part of the sound source can be specified and the pitch, intensity and timing of the musical sound to be generated can be specified.
Furthermore, although the hardware sound source in the dummy state cannot be selected from the TG selection menu in the sound source rack, it may be selected for preparation or the like. However, since the hardware sound source is not actually connected, even if a MIDI event is sent, the corresponding audio signal does not return from the hardware sound source.
Furthermore, when a device whose connection to the music LAN has been detected is associated with a music device in a dummy state, the parameters of the associated music device are transferred and synchronized before displaying the dummy state. Is changed to the active display, but only the display may be changed without performing the synchronization process.

It is a block diagram which shows the structure of the Example of the music processing apparatus of this invention. It is a figure which shows the screen of the arrangement window displayed when recording and reproducing | regenerating in the music processing apparatus of this invention. It is a figure which shows the rack screen which displays the sound source rack registered when using the soft sound source plugged in and the externally connected hardware sound source in the music processing apparatus of this invention. It is a figure which shows the data structure of the project file in the music processing apparatus of this invention. It is a figure which shows the mixer screen in the music processing apparatus of this invention. It is a figure which shows the insertion point in which an effector is inserted in the audio channel in the music processing apparatus of this invention. It is a figure which shows the data structure of the TG table in the music processing apparatus of this invention. It is a figure which shows the external sound source registration screen in the music processing apparatus of this invention. It is a figure which shows the screen of the addition registration dialog displayed when adding an external sound source in the music processing apparatus of this invention. It is a flowchart of the "add" button operation event process in the music processing apparatus of this invention. It is a flowchart of the TG library store instruction | indication event process of the desired musical instrument in the music processing apparatus of this invention. It is a flowchart of the desired port column click event process of the desired musical instrument in the music processing apparatus of the present invention. It is a flowchart of the recall instruction | indication event process of the desired musical instrument of the TG library in the music processing apparatus of this invention. It is a flowchart of the apparatus connection detection event process to music LAN in the music processing apparatus of this invention. It is a flowchart of the logical connection change event process in music LAN in the music processing apparatus of this invention. It is a flowchart of the disconnection event process of the apparatus from music LAN in the music processing apparatus of this invention. It is a flowchart of the sound source name column click event process of a desired rack in the music processing apparatus of the present invention. It is a flowchart of the process which returns to the state before performing in step S84 of the sound source name column click event process of the desired rack in the music processing apparatus of this invention. It is a flowchart of the process put into the rack performed by step S86 of the sound source name column click event process of the desired rack in the music processing apparatus of this invention. It is a flowchart of the port selection operation event process in the music processing apparatus of this invention. It is a flowchart of the effector name column click event process of the desired channel of the audio mixer in the music processing apparatus of the present invention. It is a flowchart of the process which returns to the state before performing in step S124 of the effector name column click event process of the desired channel of an audio mixer in the music processor of this invention. It is a flowchart of the process inserted in the channel performed by step S126 of the effector name column click event process of the desired channel of an audio mixer in the music processing apparatus of this invention. It is a flowchart of the project load process in the music processing apparatus of this invention. It is a flowchart of the project save process in the music processing apparatus of this invention. It is a figure which shows simply the remote control when a music apparatus is connected to the music processing apparatus of this invention. It is a figure which shows an example of the logical connection screen in music LAN in the music processing apparatus of this invention. It is a block diagram which shows the structural example of personal computer PC which implement | achieves the music processing apparatus of this invention.

Explanation of symbols

1 Music processing device, 2 DAW, 3a HDD, 3b Flash memory, 4 RAM, 5 CPU, 6 ROM, 7 Display, 8 Operator, 9 I / F, 11 GUI control unit, 12 Various instrument plug-ins, 13 MIDI Track & MIDI mixer control unit, 14 remote control unit, 15 audio track & audio mixer control unit, 16 various effect plug-ins, 17 OS API, 20 driver group, 21 various MIDI drivers, 22 S communication driver, 23 various WAVE drivers, 25 Music I / O, 30 Music LAN, 31-34 Music equipment, 40 Arrange window, 40a Edit button, 40b Track type column, 40c Track name column, 40d Output destination column, 40e Event display section, 41 Operation buttons, 42 Rack screen, 4 2a sound source rack name, 42b sound source name column, 42c mute button, 42d edit button, 43 project file, 44 mixer screen, 44a input, 44b output, 44c effector, 44c 'insertion point, 44d edit button, 44e mute, 44f pan 44g fader, 44h level meter, 46 external sound source registration screen, 47 additional registration dialog, 48 logic connection screen, 48a PC, 48b, 48c hardware sound source, 48d, 48e hardware effector, 48f “execute” button, 48g “close” Button, 48h, 48i mark, 50a R control module, 51 music equipment, 51a UI, 51b control program

Claims (3)

A series of music processing such as recording / playback, editing, and mixing of performance events and audio signals can be executed, and the music device having a predetermined music function can be externally connected and set for use. A music processing apparatus that can use a music function of a device as part of the music processing,
Track data storage means for storing track data recording performance events and audio signals;
Interface means for connecting the music processing device to a network;
A connection detection unit that detects an external device connected to the network and acquires specific information for specifying the external device;
For each external device set for use, parameter storage means for storing parameters for remotely controlling the device;
An area for selecting and setting an arbitrary external device among the external devices detected by the connection detection unit in accordance with a user setting operation, and storing parameters of the external device in the parameter storage unit And use setting means for synchronizing parameters between the external device and the parameter storage means,
Based on parameters stored in the parameter storage means, remote control means for performing remote control of each external device set for use;
File storage means for storing a plurality of project files;
In response to a user save instruction, at least the track data stored in the track data storage unit, the specific information of the external device set to be used by the use setting unit, and the use setting stored in the parameter storage unit A writing unit that generates one project file including parameters of the external device and stores the generated project file in the file storage unit;
One project file designated from the file storage means is read in response to a user read instruction, the track data contained in the read project file is stored in the track data storage means, and the parameters are stored in the parameter storage means And the external device detected by the connection detecting means is associated with the external device set to be used when saving the project file based on the specific information of the external device. Reading means for synchronizing parameters between the external device and the parameter storage means by transferring the parameters stored in the parameter storage means to the external equipment;
Display means for performing display related to each external device registered for use, and when the project file is read by the reading means, among the external devices registered for use, the devices that have been associated with each other And a display means for displaying different modes on the device that could not be performed,
A music processing apparatus capable of restoring a remote control state of a music device set to be used in the project file. A series of music processing such as recording / playback, editing, and mixing of performance events and audio signals can be executed, and the music device having a predetermined music function can be externally connected and set for use. A music processing apparatus that can use a music function of a device as part of the music processing,
Track data storage means for storing performance data and track data of audio signals;
Interface means for connecting the music processing device to a music network capable of real-time transmission of the performance event and the audio signal;
Connection detecting means for detecting the external device connected to the network;
Use setting means for setting the use of an arbitrary external device among the external devices whose connection is detected;
Setting information storage means for storing setting information of the external device set to be used;
A project file in which at least performance event track data, specific information indicating a music device set to be used, and setting data of each registered music device is recorded is read, and the track data of the read project file is read. Reading means for storing in the track data storage means, and storing setting data in the setting data storage means;
When the project file is read by the reading unit, the music device detected by the connection detecting unit is associated with the music device indicated by the specific information of the project file, and the music that can be associated An associating means for performing remote setting of the music device based on setting data corresponding to the project file for the device;
The correlating means comprises dummy means for dumming the display relating to the music device that could not be correlated;
A music processing apparatus capable of restoring a remote control state of a music device set to be used in the project file. The setting data of the music device includes parameters for controlling the operation of the music function in the music device, and a logical connection state of the performance data and audio signal transmission paths between the music device and the music processing device in the network. Connection data indicating
By the remote setting by the associating means, the operation of the music function of the music device set to be used in the project file and the logical connection of the transmission path between the music device and the music processing device in the network are restored. The music processing apparatus according to claim 2, wherein the music processing apparatus is configured to be able to do this.

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