JP2005326536A - Musical performance data processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To conduct transposition, which is made in a desirable manner as much as possible, even though the key of an objective music is changed in the middle and to prevent the occurrence of transposition which is against the will of a user. <P>SOLUTION: A music represented by automatic playing data that include pitch data, in which pitches of a series of notes are respectively represented, is transposed to a target key by the transposition method selected from three kinds of transposition methods indicated below by a program process. In a first transposition method, the entire music is transposed to the target key on the basis of the key having a highest appearance frequency (steps S16 and S19 to S22). In a second transposition method, the entire music is transposed to the target key on the basis of the key at the location of first note data (steps S16 and S23 to S26). In a third transposition method, notes belonging to an effective range are transposed to the target key for every effective range of each key on the basis of each key included in the playing data (steps S16 and S27 to S30). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a performance data processing apparatus for changing performance data representing a musical composition composed of a series of notes and transposing the musical composition represented by the performance data.

Conventionally, as shown in, for example, Patent Document 1 below, pitch data in performance data that represents pitched music including pitch data each representing a pitch of a series of notes, It is known to change the music of an arbitrary key to a predetermined key by changing according to the gap between the key and the target key.
JP 2002-23755 A

  However, the above-mentioned conventional apparatus automatically shifts the pitch represented by the pitch data in the performance data according to the gap between the key of the target song and the target key, so that the target song is transposed. When there are a plurality of tones in one piece of music as in the case where the user is present, an undesired transposition may be performed or a transposition contrary to the intention of the user may be performed. For example, when the key that is assumed to be the key of the target song is a key in only a very short section of the music, the key in many sections of the music is different from the target key. Also, if the key that is considered to be the key of the target song is not the key at the position of the note that appears first in the performance data, when the performance data is played, the performance is performed in a key different from the target key. Be started. Furthermore, since the key of the target song is automatically changed to the target key, a key unintended by the user may suddenly appear due to the modulation in the music.

  The present invention has been made in order to cope with the above-described problem, and even when the target song is transposed in the middle, a preferable transposition is performed as much as possible, and a transposition contrary to the intention of the user is not performed. The object is to provide a performance data processing apparatus.

  In order to achieve the above object, the feature of the present invention is that a key that appears in a musical composition based on performance data that includes musical pitch data each including a pitch data that represents a pitch of a series of musical notes. A key detection means for detecting, a key extraction means for extracting a key with the highest appearance frequency among the detected keys, and a performance according to a difference between the extracted key and a predetermined or selected key There is provided transposition means for changing pitch data in the data and transposing the music represented by the performance data. According to this, since the key in most sections of the music is changed to a key determined or selected in advance, even if the music is transposed in the middle, there is no big trouble. At the same time, it is possible to avoid greatly contrary to the intention of the user.

  Another feature of the present invention is that a key extraction means for detecting a position of a note that first appears in the performance data as described above, and extracting a key at the position of the detected note, and the extraction Transposing means for transposing the musical piece represented by the performance data by changing the pitch data in the performance data in accordance with the difference between the key and the predetermined or selected key. According to this, with respect to the first note of the music, since it will be changed to a key determined or selected in advance, even if the music is transposed in the middle, it will not cause a big trouble, It is possible to avoid greatly contrary to the intention of the user at the start of music.

  Another feature of the present invention is that a key detecting means for detecting a key appearing in the music based on the performance data as described above, and the detected key in the performance data for each detected key. Effective range detection means for detecting an effective range, and for each detected effective range, the pitch data in the performance data is changed according to a gap between the detected key and a predetermined or selected key. And transposing means for transposing the music represented by the performance data. According to this, since the entire music is transposed to the same key, even if the music is transposed in the middle, it does not cause a big trouble and greatly contradicts the intention of the user at the start of the music. Can be avoided.

  Another feature of the present invention is that a transposition method storage means for storing a plurality of algorithms each defining a plurality of transposition methods for transposing music, and one algorithm among the plurality of stored algorithms. There is provided selection means for selecting, and transposition means for transposing the musical piece represented by the performance data by changing the pitch data in the performance data as described above according to the selected algorithm. According to this, since the user can arbitrarily select a transposition method, even when the music is transposed in the middle, transposition in accordance with the user's intention can be realized.

  Hereinafter, an electronic music apparatus to which a performance data processing apparatus according to an embodiment of the present invention is applied will be described. FIG. 1 is a block diagram schematically showing this electronic music apparatus. The electronic music apparatus includes a keyboard-type electronic musical instrument, a non-keyboard-type electronic musical instrument (an electronic musical instrument having touch plates, push buttons, strings, etc. as performance operators), an automatic performance apparatus (sequencer apparatus), and a personal having an automatic performance function. A computer can be considered.

  This electronic music apparatus has an input operator group 11, a display 12, and a musical tone signal generation circuit 13. The input operator group 11 includes a plurality of operators for instructing the operation of the electronic music apparatus, and the operations of the plurality of operators are detected by a detection circuit 14 connected to the bus 20. The plurality of operators include a switch operator, a volume operator, a mouse, a cursor movement key, and the like. In a keyboard-type electronic musical instrument, a white key and a black key are also included. The display 12 includes a liquid crystal display, a CRT, and the like, and displays characters, numbers, figures, and the like. The display mode of the display 12 is controlled by a display control circuit 15 connected to the bus 20. The musical tone signal generating circuit 13 is connected to the bus 20 and forms a musical tone signal based on performance data supplied under the control of the CPU 31, and gives an effect to the formed musical tone signal to produce a sound system. 16 is output. The sound system 16 includes an amplifier and a speaker.

  The electronic music apparatus includes a CPU 31, a timer 32, a ROM 33, and a RAM 34 that are connected to the bus 20 and constitute a microcomputer main body, and also includes an external storage device 35 and a communication interface circuit 36. . The external storage device 35 includes various recording media such as a hard disk HD preinstalled in the electronic music device, a compact disc CD that can be mounted on the electronic music device, and a flexible disk FD, and a drive unit for each of the recording media. It is possible to store and read a large amount of data and programs. In the case of the present embodiment, the hard disk HD stores automatic performance data corresponding to a plurality of music pieces in addition to the transposition program of FIG. 2 and various programs including an automatic performance program (not shown) for reproducing automatic performance data. ing. These programs and automatic performance data are stored in advance in the hard disk HD, supplied to the hard disk HD from a compact disk CD, a flexible disk FD, or the like, or from the outside via the external device 41 or the communication network 42 described later. To be supplied.

  Automatic performance data includes key data that represents a key, note data that represents a series of notes, tone data that represents the tone of a tone signal that is generated, volume data that represents the volume of a tone signal that is generated, etc. For example, it is configured in accordance with the MIDI standard. Each note data includes pitch data representing a pitch, velocity data representing a volume, and the like.

  The communication interface circuit 36 can be connected to an external device 41 such as another electronic musical instrument or a personal computer, and the electronic music apparatus can communicate various programs and data with the external device 41. For example, a performance device such as a keyboard may be adopted as the external device 41, and performance information may be input from the external device 41 in place of or in addition to the performance performed by the performance operators constituting the input operator group 11. The communication interface circuit 36 can also be connected to the outside via a communication network 42 such as the Internet so that the electronic music apparatus can receive various programs and data from the outside or transmit them to the outside. It has become.

  Next, the operation of the embodiment configured as described above will be described. The user operates the input operator group 11 to cause the CPU 31 to execute the transposition program shown in FIG. The execution of the transposition program is started in step S10, and the CPU 31 inputs a desired music piece selected by the user by operating the input operator group 11 in step S11. Then, automatic performance data corresponding to the input music is read from the external storage device 35 and written into the RAM 34. If the automatic performance data of the music desired by the user is not stored in the external storage device 35, the desired automatic performance data is received from the external device 41 that stores other automatic performance data via the communication interface circuit 36. The desired automatic performance data may be read from the outside via the communication interface circuit 36 and the communication network 42.

  Next, in step S12, the CPU 31 inputs a target tone instructed by the user by operating the input operator group 11. After the process of step S12, the CPU 31 inputs a user instruction regarding transposition by the operation of the input operator group 11 and sets various rules regarding transposition at step S13. Some of these rules include a key detection method for detecting the key included in the music represented by the automatic performance data, a method for calculating the pitch shift value during transposition, the addition, deletion, and editing of the transposition method. It is included. As a key detection method, there are a method of detecting a key by extracting key data included in automatic performance data, a method of detecting a key by analyzing automatic performance data, and the like.

  The pitch shift value is calculated by a method in which the pitch shift value representing the difference between the original key and the target key is always a positive value (0 to +11), and the pitch shift value is always negative. And the like, and the method of making the pitch shift value positive and negative values (−5 to +6 or −6 to +5) that minimize the absolute value. is there.

  The addition and deletion of the transposition method means adding or deleting the type of transposition method selected by the user in the next steps S14 and S15, respectively. Also, editing the transposition method means editing the transposition method selected by the user. These transposition methods are stipulated in detail by an algorithm by program processing described later. Note that the process of step S12 may be omitted, and the various rules may be unchangeable while being determined in advance.

  After the process of step S13, the CPU 31 displays a plurality of types of transposition methods set in step S13 on the display 12 in step S14. In the display of this transposition method, as shown in FIG. 3, for example, “transpose based on the key having the highest appearance frequency”, “transpose based on the key at the position of the first note data”, and “performance Three types of “transpose for each effective range of each key based on each key included in the data” are displayed. In step S15, the user waits for an instruction to select a transposition method. When the user operates the input operator group 11 and selects any one of the transposition methods being displayed, “Yes” is determined in step S15, and the process proceeds to step S16. If the user does not select any transposition method, it may be considered that any predetermined transposition method has been selected.

  In step S16, all the keys appearing in the selected music are detected. Specifically, the key is detected according to the key detection method set in step S13, based on the automatic performance data selected and written in the RAM 34. For example, as shown in FIG. 4, if all musical pieces are 14 bars and the key changes like Amaj, Bmaj, Emaj, Bmaj, Emaj over the 1st to 14th bars, all these keys are detected. Is done.

  Next, in steps S17 and S18, it is determined which transposition method has been selected by the process of step S15. If “transpose based on the key with the highest appearance frequency” is selected as the transposition method, “Yes” is determined in step S17, and the process proceeds to step S19. In step S19, the length of the effective range in the automatic performance data is checked for each key detected by the process in step S16. Taking the music shown in FIG. 4 as an example, Amaj, Bmaj, Emaj, Bmaj, and Emaj are in this order: first measure, second to fourth measures, fifth to eighth measures, ninth to tenth measures, and first to first measures. That's 14 bars. In step S20, the length of the effective range is added up for each detected key type. Note that parallel tones are regarded as the same type of tone. As a result, taking the music of FIG. 4 as an example, Amaj, Bmaj, and Emaj are 1 bar length, 5 bar length, and 8 bar length, respectively.

  Next, in step S21, a pitch shift value is calculated on the basis of the key having the longest effective range. Specifically, according to the pitch shift value calculation method set by the process of step S13, the difference between the reference key and the target key (that is, the pitch difference) is calculated. Taking the music shown in FIG. 4 as an example, Emaj, which is eight measures long, is determined as a reference key. If the target key is Cmaj and the calculation method of the pitch shift value is a method of “making positive and negative values that minimize the absolute value”, the pitch shift value is “−4”. " If the calculation method of the pitch shift value is a method of “making the pitch shift value always positive”, the pitch shift value is “+8”. If the calculation method of the pitch shift value is a method of “making the pitch shift value always a negative value”, the pitch shift value is “−4”.

  In step S22, the entire music represented by the automatic performance data is transposed to the target key. Specifically, the calculated pitch shift value is added to all pitch data in the automatic performance data. As a result, taking the musical piece of FIG. 4 as an example and the target key is Cmaj, the first measure, the second to fourth measures, the fifth to eighth measures, the ninth to tenth measures, and the first to fourteenth measures from the beginning. In this order, Fmaj, Gmaj, Cmaj, Gmaj, and Cmaj change. After step S22, the transposition program is terminated in step S31.

  If “Transpose based on the key at the position of the first note data” is selected as the transposition method, “Yes” is determined in step S18, and the process proceeds to step S23. In step S23, the automatic musical performance data corresponding to the selected music and written in the RAM 34 are sequentially read from the head to detect the first note data. If the note data is not detected, the transposition program is terminated in step S31 based on the determination of “No” in step S24. On the other hand, if the first note data is detected, “Yes” is determined in step S24, and the pitch shift value is calculated based on the key at the position of the first note data in step S25. A specific processing method is the same as the processing method in step S21 described above. Taking the musical piece of FIG. 4 as an example, Bmaj at the position of the first note data shown in the note string column is determined as the reference key.

  In step S26, the entire music represented by the automatic performance data is transposed to the target key using the pitch shift value in the same manner as in step S21. As a result, taking the musical piece of FIG. 4 as an example and the target key is Cmaj, the first measure, the second to fourth measures, the fifth to eighth measures, the ninth to tenth measures, and the first to fourteenth measures from the beginning. In this order, Bbmaj, Cmaj, Fmaj, Cmaj, and Fmaj change. After step S26, the transposition program is terminated in step S31.

  Further, if “transpose for each effective range of each key based on each key included in the performance data” is selected as the key transposition method, both “No” are determined in steps S17 and S18. The circulation process of steps S27 to S30 is executed until all the processes related to the key detected by the process of step S16 are completed. In this circulation processing, in step S27, the effective range is temporarily stored with reference to one of the detected keys from the beginning of the automatic performance data corresponding to the selected music and written in the RAM 34. . In step S28, a pitch shift value is calculated for each effective range with reference to the key in which the effective range is detected. A specific processing method is the same as the processing in step S21 described above. Taking the musical piece of FIG. 4 as an example, Amaj, Bmaj, Emaj, Bmaj, and Emaj are determined as reference keys in order from the top.

  Then, in step S29, as in the process of step S21, the pitch shift of the notes represented by the automatic performance data and included in the effective range for each effective range is determined for each effective range. Transpose to the desired key using the value. As a result, taking the music of FIG. 4 as an example, if the target key is Cmaj, the entire music is changed to Cmaj. After the circulation process consisting of the steps S27 to S30, in step S31, the execution of the transposition program is terminated.

  The automatic performance data in the RAM 34 relating to the music transposed in this way can be reproduced by a reproduction program (not shown). According to the execution of this reproduction program, note data, tone color data, volume data, and the like constituting the automatic performance data are sequentially read out according to the progress of the music (that is, the passage of time) and supplied to the musical tone signal generating circuit 13 for the musical tone signal. The generating circuit 13 generates a tone signal corresponding to these data. Also, by executing a program (not shown) using the transposed music automatic performance data, a lamp (not shown) provided on the keyboard of the input operator group 11 is turned on, and a music performance guide is provided to the user. Can also be performed. Furthermore, the musical score of the transposed music can be displayed on the display device 12 by executing a program (not shown) using the automatic performance data of the transposed music. If the automatic performance data of the transposed music is stored in the external storage device 35, it can be used later.

  As can be understood from the above description of operation, according to the above embodiment, the music represented by the automatic performance data based on the key having the highest appearance frequency is the target by the algorithm comprising the processes of steps S16 and S19 to S22. Since the key is transposed to the key, the key in the most part of the music is changed to the target key. Therefore, even when the music is modulated in the middle, it does not cause a big trouble, and it is possible to avoid greatly contrary to the intention of the user. In addition, since the music represented by the automatic performance data is transposed to the target key based on the key at the position of the first appearing note by the algorithm composed of the processes of steps S16 and S23 to S26, the first note of the music Is always changed to the desired key. Therefore, even when the music is modulated in the middle, it does not cause a big trouble, and it can be avoided that it is contrary to the intention of the user at the start of the music.

  In addition, the algorithm composed of the processes of steps S16 and S27 to S30 is changed to the target key based on the key in the music for each effective range of the key appearing in the music, so that the music is transposed in the middle. Even if it is, it does not cause a big trouble, and it can avoid greatly contrary to a user's will at the time of the start of music. Furthermore, since the music is transposed according to one algorithm selected by the user from among a plurality of algorithms that respectively define a plurality of transposition methods by the processing of steps S15, S17, and S18, the music is transposed in the middle. Even if it is, the transposition according to a user's will is realizable.

  Furthermore, in carrying out the present invention, the present invention is not limited to the above embodiment and its modifications, and various modifications can be made without departing from the object of the present invention.

  For example, in the above-described embodiment, three types of transposition methods have been described. However, the present invention is not limited thereto, and other transposition methods may be selected. For example, the key represented by the key data recorded first in the automatic performance data may be used as the reference key. In the example of FIG. 4, the reference key in this case is Amaj. In addition, the user may directly instruct the input of the reference key.

  Further, in the above embodiment, the user designates the target key by the process of step S12. However, instead of this, it may be fixed to a predetermined basic key such as Cmaj or Amin. In the above embodiment, the key range in steps S19, S20, and S27 to S29 is set to the bar length. The unit of the key range is, for each note, the number of clocks in MIDI data, the absolute time, etc. It may be. Furthermore, in the above-described embodiment, the automatic performance data conforms to the MIDI standard, but the present invention is applied even if the automatic performance data does not conform to the MIDI standard. The automatic performance data may include chord data representing chords and style data representing accompaniment styles.

1 is an overall block diagram of an electronic music apparatus according to an embodiment of the present invention. It is a flowchart which shows the transposition program performed with the said electronic music apparatus. It is a figure showing the selection screen of the transposition method in a display. It is a figure for demonstrating the change state of the key which appears in a music.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Input operator group, 12 ... Display, 13 ... Musical tone signal generation circuit, 31 ... CPU, 33 ... ROM, 34 ... RAM, 35 ... External storage device, 36 ... Communication interface circuit

Claims (4)

A key detection means for detecting a key appearing in the music piece based on performance data representing the music piece composed of the same series of notes, including pitch data each representing the pitch of a series of notes;
Key extraction means for extracting the key with the highest appearance frequency among the detected keys;
Transposing means for transposing the musical piece represented by the performance data by changing pitch data in the performance data in accordance with a gap between the extracted key and a predetermined or selected key. Performance data processing device. Detects the position of the first note that appears in the performance data that represents the music composed of the same series of notes, including pitch data that represents the pitch of each series of notes, and adjusts the key at the position of the detected notes. Key extraction means for extracting;
Transposing means for transposing the musical piece represented by the performance data by changing pitch data in the performance data in accordance with a gap between the extracted key and a predetermined or selected key. Performance data processing device. A key detection means for detecting a key appearing in the music piece based on performance data representing the music piece composed of the same series of notes, including pitch data each representing the pitch of a series of notes;
Effective range detecting means for detecting an effective range of the detected key in the performance data for each detected key;
A musical piece represented by the performance data by changing pitch data in the performance data in accordance with a gap between the detected key and a predetermined or selected key for each detected effective range. A performance data processing apparatus comprising a transposition means for transposing the sound. A transposition method storage means for storing a plurality of algorithms each defining a plurality of transposition methods for transposing music;
Selecting means for selecting one algorithm from the plurality of stored algorithms;
The pitch data in the performance data representing the music composed of the same series of notes including the pitch data each representing the pitch of the series of notes is changed according to the selected algorithm, and the music represented by the performance data is changed. A performance data processing apparatus comprising transposition means for transposing.

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