JP5669646B2 - Performance evaluation device, electronic musical instrument and program - Google Patents

Description

  The present invention relates to a performance evaluation apparatus, an electronic musical instrument, and a program.

  Fingering state detection that detects the fingering state of the performer by generating a magnetic field from each finger operated by the performer and detecting changes in the magnetic flux density of the magnetic field applied to each of the plurality of performance operators. An apparatus is known (see, for example, Patent Document 1).

  A performance evaluation system for comparing the performance of the keyboard device by comparing the image of the hand being played in the model performance data with the image of the hand being played captured by the imaging means and determining the comparison result. It is known (see, for example, Patent Document 2).

  There is also known an electronic musical instrument with a practice function that can perform performance error determination by comparing key press information of performance performed in accordance with practice instructions based on sample performance information with sample performance information (for example, Patent Documents). 3).

  Also, it is classified as “finger spread”, “finger pegging”, “finger straddle”, etc., and the location where these fingering operations should be performed is specified from the model performance data, and the specified location in the performance data played by the user It is known that a performance technique related to a user's “fingering movement” is diagnosed by comparing corresponding data with model performance data (see, for example, Patent Document 4).

Japanese Patent Laid-Open No. 7-197991 JP 2006-91633 A JP 2007-286087 A JP 2002-108198 A

  The objective of this invention is providing the performance evaluation apparatus, the electronic musical instrument, and program which can perform evaluation regarding fingering of performance.

  The performance evaluation apparatus of the present invention includes a storage unit that stores sample pronunciation information including note information in which notes and finger numbers to which the notes are to be played are associated, and the played pronunciation information and the sample pronunciation information And detecting a difference in sound generation timing and / or velocity of both notes for each finger number, and detecting the finger according to the difference for each finger number detected by the detection unit. And an output unit that outputs performance evaluation of the finger corresponding to the number.

  By outputting the performance evaluation of the finger corresponding to the finger number, it is possible to obtain an evaluation regarding the fingering of the performance.

It is a block diagram which shows the structural example of the electronic musical instrument which has a performance evaluation apparatus by the 1st Embodiment of this invention. It is a flowchart which shows the example of the performance evaluation process which the electronic musical instrument of FIG. 1 performs. It is a flowchart which shows the detail of a process of step S209 of FIG. FIG. 4A is a diagram showing an example of model pronunciation information, and FIG. 4B is a diagram showing an example of performance pronunciation information. It is a figure which shows the example of the histogram for every finger number. It is a figure which shows the example of a histogram. It is a figure which shows the example of the example pronunciation information by the 2nd Embodiment of this invention. It is a flowchart which shows the example of the presentation process of the practice music based on performance evaluation. It is a figure which shows the example of the example pronunciation information by the 3rd Embodiment of this invention. FIG. 10A is a diagram showing an example of a histogram for each fingering, and FIG. 10B is a diagram showing an example of a total histogram. It is a block diagram which shows the structural example of the performance evaluation apparatus by the 4th Embodiment of this invention.

(First embodiment)
FIG. 1 is a block diagram showing a configuration example of an electronic musical instrument having a performance evaluation apparatus according to the first embodiment of the present invention. A CPU 101, ROM 102, RAM 103, liquid crystal display (LCD) 104, external storage medium 105, external input / output interface 106, key scan circuit 108, panel scan circuit 110, and tone generator 112 are connected to the bus 107. The keyboard 109 is a performance operator for performing a performance having a plurality of white keys and black keys. The key scan circuit 108 outputs a note on event or a note off event to the CPU 101 in response to a key pressing operation or a key releasing operation on the keyboard 109. Panel 111 includes a switch and a corresponding light emitting diode. The panel scan circuit 110 outputs the operation information to the CPU 101 in response to a switch operation on the panel 111. The liquid crystal display 104 displays performance evaluation results and the like.

  The tone generator 112 receives a tone parameter from the CPU 101 to generate a tone signal and outputs it to the D / A converter 113. The musical tone parameters include a note-on event and a note-off event of the keyboard 109, operation information of the panel 111, and the like. The D / A converter 113 converts the musical sound signal from a digital format to an analog format. The analog signal processing unit 114 performs processing for adjusting an analog tone signal and outputs the processed signal to the amplifier 115. The amplifier 115 amplifies the musical sound signal and outputs it to the speaker 116. Musical sounds are produced from the speaker 116.

  The ROM 102 includes a waveform memory that stores a plurality of musical sound waveforms (tone color data). The tone generator 112 performs sound generation processing and mute processing based on the tone waveform stored in the waveform memory. In addition, the ROM 102 stores a computer program. The CPU 101 executes the computer program to perform the processes of FIGS. 2 and 3 described later. The RAM 103 has a work area for the CPU 101 and the like. The external storage medium 105 is a flexible disk or the like, and can store performance data, a computer program, and the like. The external input / output interface 106 is, for example, MIDI (musical instrument digital interface) or the like, and can perform input / output of performance data (MIDI data) to the outside.

  FIG. 4A is a diagram showing an example of song sample pronunciation information 401 stored in the ROM 102 or the external storage device 105. The model pronunciation information 401 includes a plurality of note information 411. The note information 411 includes a key number 421, a step time 422, a gate time 423, a velocity 424, and a finger number 425. The key number 421 indicates the pitch of the note to be generated. The step time 422 indicates the tone generation timing (key press timing) of the note based on the measure data or the beat data. The gate time 423 indicates the length of a musical note to be played (the length from key depression to key release). Velocity 424 indicates a key pressing speed (volume). The finger number 425 is the number of ten fingers of both hands, and indicates the number of the finger that should play the note. As described above, the storage unit such as the ROM 102 or the external storage device 105 stores the example pronunciation information 401 including the note information 411 in which the note and the finger number 425 to which the note is to be played are associated. The pronunciation information 401 can be read from the storage unit.

  There is fingering practice as practice of performance. In the performance as a model, fingering is determined according to the music, and a finger to play the note is designated for each note. By playing with a designated finger for each note, it is possible to realize a smooth performance with a desired sound volume (key press speed). Fingering practice is extremely important. Since the model pronunciation information 401 has a finger number 425 for each note, it is possible to evaluate fingering with respect to the performance of the performer.

  FIG. 2 is a flowchart showing an example of performance evaluation processing performed by the electronic musical instrument of FIG. In step S201, the CPU 101 records the performance of the performer. First, the performer selects a song to practice with the song selection switch on the panel 111 and presses the recording switch. Then, the CPU 101 reads out the accompaniment data of the selected song from the ROM 102 or the external storage medium 105 and reproduces it, or reproduces a metronome sound. The performer plays the selected song by operating the keyboard 109. The CPU (recording unit) 101 records (records) performance sound generation information 402 (FIG. 4B) in the RAM 103 in accordance with the performance operation of the keyboard 109.

  FIG. 4B is a diagram showing an example of the musical performance pronunciation information 402. The performance pronunciation information 402 has a plurality of key press information (note information) 412. The key pressing information 412 is obtained by deleting the finger number 425 from the note information 411 in FIG. 4A, and has a key number 421, a step time 422, a gate time 423, and a velocity 424. The CPU 101 records the pitch of the pressed key as the key number 421. Further, the CPU 101 records the key pressing timing (note generation timing) based on the measure data or beat data as the step time 422. Further, the CPU 101 records the length from the key pressing operation to the key releasing operation (note length) as the gate time 423. Further, the CPU 101 records the key pressing speed (volume) as a velocity 424.

  Next, in step S202 of FIG. 2, the CPU 101 sequentially reads the note information 411 within the effective range of the model pronunciation information 401 from the ROM 102 or the external storage medium 105 from the head timing. Next, in step S203, the CPU 101 searches for the key pressing information 412 of the performance pronunciation information 402 in FIG. 4B within the effective range. Since the performance pronunciation information 402 is a recording of the performance of the performer, a difference in sound generation timing may occur with respect to the model pronunciation information 401. Therefore, in step S203, the key press information 412 of the performance pronunciation information 402 within the effective range before and after the sound generation timing of the note information 411 of the model pronunciation information 401 is searched for as a reference.

  Next, in step S204, the CPU 101 checks whether or not the key pressing information 412 is within the above effective range. If there is key pressing information 412, the process proceeds to step S205, and if there is no key pressing information 412, the process proceeds to step S212. In step S205, the CPU 101 acquires the number of key presses corresponding to the number of key press information 412 within the valid range. Next, in step S206, it is checked whether or not the number of key press information 412 within the effective range of the performance pronunciation information 402 is smaller than the number of note information 411 within the effective range of the model pronunciation information 401. If it is less, there is no sound and the process proceeds to step S207. If not, the process proceeds to step S208. In step S207, the CPU 101 adds the number of sound omissions to the sound omission counter, and proceeds to step S208. Similarly, in step S212, the CPU 101 adds the number of key presses that is insufficient with respect to the model pronunciation information 401 to the sound omission counter as the number of omissions, and proceeds to step S213.

  In step S208, the CPU 101 acquires key pressing information 412 within the effective range in order from the top timing. Next, in step S209, the CPU 101 compares the note information 411 of the model pronunciation information 401 with the key pressing information 412 of the performance pronunciation information 402, and the difference between the step times (note generation timing) 422 and / or Deviations in velocity 424 are accumulated and detected for each finger number. Details of step S209 will be described with reference to FIG.

  FIG. 3 is a flowchart showing details of the process in step S209 of FIG. In step S301, the CPU 101 compares the note information 411 of the sample pronunciation information 401 with the key pressing information 412 of the performance pronunciation information 402, and accumulates and detects the difference between the step times (note generation timings) 422 of both. . That is, the CPU 101 generates and updates a histogram 520 (FIG. 5) of the total deviation of the step time (sound generation timing) 422 regardless of the finger number 425.

  FIG. 6 is a diagram illustrating an example of the histogram 520. The horizontal axis indicates the amount of deviation of the step time (note generation timing) 422, and the vertical axis indicates the number of times (frequency). A histogram 520 is generated by accumulating the number of times for each deviation amount of the step time (note generation timing) 422. The histogram 520 is obtained by accumulating the number of deviations for all key pressing information 412 regardless of the finger number 425. By generating the histogram 520, it is possible to perform performance evaluation such as when the player's key pressing timing is faster or slower overall.

  Next, in step S302 of FIG. 3, the CPU 101 compares the note information 411 of the model pronunciation information 401 with the key pressing information 412 of the performance pronunciation information 402, and the difference between the step times (note generation timings) 422 of both of them. Are accumulated for each finger number 425 and detected. That is, the CPU 101 generates and updates histograms 500 to 509 (FIG. 5) of deviation of the step time (sound generation timing) 422 for each finger number 425. The histograms 500 to 509 in FIG. 5 are histograms corresponding to the finger numbers 425 of the ten fingers of both hands, and are generated in the same manner as the histogram of FIG. When the finger number 425 of the note information 411 of the model pronunciation information 401 is 0, the number of shifts is accumulated in the histogram 500 of the number 0 finger number. Similarly, when the finger numbers 425 of the note information 411 of the model pronunciation information 401 are 1 to 9, the number of deviations is accumulated in the histograms 501 to 509 of the first to ninth finger numbers, respectively. By generating the histograms 500 to 509, it is possible to perform performance evaluation such as, for example, when the left-hand ring finger is pressed early or late on average.

  In this embodiment, finger numbers actually played by the performer are not detected. The histogram is generated on the assumption that the performer has performed with the finger of the finger number 425 indicated in the model pronunciation information 401.

  Next, in step S303 of FIG. 3, the CPU 101 compares the note information 411 of the model pronunciation information 401 and the key press information 412 of the performance pronunciation information 402, and accumulates and detects the deviation of the velocity 424 of both. That is, the CPU 101 generates and updates the histogram 521 (FIG. 5) of the total deviation of the velocity 424 regardless of the finger number 425. The histogram 521 in FIG. 5 is generated in the same manner as the histogram in FIG. 6, the horizontal axis indicates the amount of deviation of the velocity 424, and the vertical axis indicates the number of times (frequency). A histogram 521 is generated by accumulating the number of times for each deviation amount of the velocity 424. The histogram 521 is an accumulation of the number of deviations for all key pressing information 412 regardless of the finger number 425. By generating the histogram 521, it is possible to evaluate performance such that the velocity of the player's key press (key press speed) is fast or slow overall.

  Next, in step S304 in FIG. 3, the CPU 101 compares the note information 411 of the model pronunciation information 401 and the key press information 412 of the performance pronunciation information 402, and accumulates the deviation of the velocity 424 for each finger number 425. To detect. That is, the CPU 101 generates and updates the histograms 510 to 519 (FIG. 5) of the deviation of the velocity 424 for each finger number 425. The histograms 510 to 519 in FIG. 5 are histograms corresponding to the finger numbers 425 of the ten fingers of both hands, and are generated in the same manner as the histogram of FIG. When the finger number 425 of the note information 411 of the model pronunciation information 401 is 0, the number of deviations is accumulated in the histogram 510 of the finger number 0. Similarly, when the finger numbers 425 of the note information 411 of the model pronunciation information 401 are 1 to 9, the number of deviations is accumulated in the histograms 511 to 519 of the first to ninth finger numbers, respectively. By generating the histograms 510 to 519, it is possible to perform performance evaluation, for example, that the key pressing speed of the left finger is fast or slow on average.

  Next, in step S <b> 210 of FIG. 2, the CPU 101 includes an extra note (note) that is not included in the note information 411 of the sample pronunciation information 401 in the key press information 412 of the performance pronunciation information 402 within the effective range. Check whether or not. If there are extra notes, the process proceeds to step S211, and if there are no extra notes, the process proceeds to step S213. In step S211, the CPU 101 adds the number of extra notes to the mistouch counter as a mistouch of the player's performance operation, and proceeds to step S213.

  In step S213, the CPU 101 checks whether or not the processing of all key pressing information 412 within the effective range has been completed. If completed, the process proceeds to step S214. If not completed, the process returns to step S208, and the CPU 101 obtains the key pressing information 412 at the next timing within the effective range, and repeats the same processing as described above.

  In step S214, the CPU 101 checks whether or not the processed effective range is the end of the song. If it is not the last, the process proceeds to step S215, and if it is the last, the process proceeds to step S216. In step S215, the CPU 101 shifts the effective range later in time, returns to step S202, and repeats the above processing.

  In step S216, the CPU 101 performs performance evaluation based on the histograms 500 to 521 in FIG. 5, the sound loss counter in steps S207 and S212, and the mistouch counter in step S211, and displays the result of the performance evaluation on the liquid crystal display 104. . The sound omission counter counts the number of omissions for each finger number 425 because the note information 411 existing in the model pronunciation information 401 is not pressed as the performance sound production information 402.

  By referring to the histograms 500 to 519 and the sound omission counter, for each finger number 425, the amount of deviation of the key pressing timing 422 and velocity 424 and the number of omissions can be known. The performance evaluation result such as “weak point: left hand ring finger” can be displayed. Alternatively, the performance evaluation results may be displayed with the worst three performance evaluations being the worst three.

  Further, by referring to the histogram 520, it is possible to display performance evaluation results such as the player's key pressing timing being early or late as a whole.

  In addition, by referring to the histograms 500 to 509, it is possible to display performance evaluation results for each finger such as, for example, an early or late key pressing timing of the ring finger of the left hand.

  Further, by referring to the histogram 521, it is possible to display performance evaluation results such as the player's key pressing speed (velocity) being fast or slow overall.

  Further, by referring to the histograms 510 to 519, it is possible to display performance evaluation results for each finger such as, for example, a fast or slow key pressing speed of the left hand ring finger.

  Further, by obtaining the average value of the histogram 520, it is possible to display performance evaluation results such as the overall key pressing timing of the entire finger being early or late. Further, by obtaining the standard deviation or variance of the histogram 520, it is possible to display the performance evaluation result of the variation in deviation of the key pressing timing of the entire finger.

  Further, by obtaining the average value of the histograms 500 to 509, it is possible to display a performance evaluation result such as an early or late key pressing timing for each finger number 425. Further, by obtaining the standard deviation or variance of the histograms 500 to 509, it is possible to display performance evaluation results of variations in key pressing timing deviation for each finger number 425.

  Further, by obtaining the average value of the histogram 521, it is possible to display performance evaluation results such as the overall key pressing speed being fast or slow as a whole. Further, by obtaining the standard deviation or variance of the histogram 521, it is possible to display the performance evaluation result of the variation in the key pressing speed deviation of the entire finger.

  Further, by obtaining the average value of the histograms 510 to 519, performance evaluation results such as a fast or slow key pressing speed can be displayed for each finger number 425. Further, by obtaining the standard deviation or variance of the histograms 510 to 519, it is possible to display the performance evaluation result of the variation of the key pressing speed deviation for each finger number 425.

  In step S216, the CPU 101 may display the performance evaluation result, or may print or output the performance evaluation result. That is, in step S216, the CPU (performance evaluation result output unit) 101 can output the performance evaluation of the finger corresponding to the finger number in accordance with the key pressing timing and / or velocity deviation for each finger number.

  According to the present embodiment, by evaluating the performance evaluation of the finger corresponding to the finger number, it is possible to obtain an evaluation regarding performance fingering.

(Second Embodiment)
FIG. 7 is a diagram showing an example of model pronunciation information 711 to 714 according to the second embodiment of the present invention. The model performance information 711 corresponds to the model performance information 401 in FIG. Hereinafter, the points of the present embodiment different from the first embodiment will be described. The model performance information 711 includes finger usage counts 700 to 709 and pronunciation information 710. The pronunciation information 710 is the same as the example performance information 401 in FIG. That is, the model pronunciation information 711 in FIG. 7 is obtained by adding the finger usage counts 700 to 709 to the model pronunciation information 401 in FIG. Ten finger use counts 700 to 709 correspond to ten finger numbers corresponding to ten fingers of both hands, and indicate the number of times each finger number is used by the finger number 425 in the pronunciation information 710. That is, ten finger usage counts 700 to 709 indicate the number of times each finger is used in the performance of one song. By referring to the ten finger usage counts 700 to 709, it is possible to know a finger with a high usage count in the song of the model pronunciation information 711. The ROM 102 or the external storage device 105 stores a plurality of example pronunciation information 711 to 714. The example pronunciation information 712 to 714 has the same configuration as the example pronunciation information 711. The model pronunciation information 711 to 714 is model pronunciation information of different songs. With the performance evaluation of the first embodiment, it is possible to know a fingering finger that is a weak point of the performer. In this embodiment, a music suitable for practicing a weak finger can be provided to the performer. If the finger of the weak point is known, the finger usage count 700 to 709 is referred to, and the player should be encouraged to practice a song with a high frequency of using the weak finger from the sample pronunciation information 711 to 714 of a plurality of songs. Can do.

  FIG. 8 is a flowchart illustrating an example of a practice song presentation process based on performance evaluation. The processing in FIG. 8 is performed by the CPU 101 executing a program. In step S801, the CPU 101 performs the same performance evaluation process as that in the flowchart of FIG. Next, in step S802, the CPU 101 detects the finger number of the weak point with the lowest performance evaluation evaluated by the performance evaluation process. Next, in step S803, the CPU 101 refers to the finger usage counts 700 to 709 of the example pronunciation information 711 to 714, and selects the finger detected above from the example pronunciation information 711 to 714 of a plurality of songs. Search for the most frequently used song. Next, in step S804, the CPU 101 displays the searched music piece on the liquid crystal display 104 as a practice music suitable for weak finger practice. For example, the CPU 101 displays “weak point: left-hand ring finger” and “next song: practice the third song”. The performer presses the “Yes” switch on the panel 111 if the presented song is acceptable, and presses the “No” switch on the panel 111 to practice another song. Next, in step S805, the CPU 101 checks which one of the “Yes” switch and the “No” switch is pressed. If the “Yes” switch is pressed, the process returns to step S801, and the above processing including recording of the presented practice song and performance evaluation is repeated. If the “No” switch is pressed, the process returns to step 803 to repeat the search from the sample pronunciation information 711 to 714 for a plurality of songs excluding the practice song presented above.

  In step S804, the CPU 101 may display the next practice song, or may print or output the sound. In other words, in step S804, the CPU (performance evaluation output unit) 101 outputs information on the practice song corresponding to the finger number with the greatest key-shift timing and / or velocity deviation. The performer can receive the presentation of music suitable for the practice of the finger of the weak point, and can practice the fingering effectively.

(Third embodiment)
FIG. 9 is a diagram showing an example of model pronunciation information 901 according to the third embodiment of the present invention. The model performance information 901 corresponds to the model performance information 711 in FIG. Hereinafter, the points of the present embodiment different from the second embodiment will be described. The model performance information 901 includes a finger usage count 902 and pronunciation information 903. The pronunciation information 903 is the same as the model performance information 401 in FIG. The finger usage count 902 corresponds to the finger usage count 700 to 709 in FIG. 100 finger usage counts 902 indicate the usage count for each fingering from the finger number 425 of the previous note to the finger number 425 of the current note. For example, a fingering with the finger number of the previous note being 0 and the finger number of the current note being 1 indicates fingering from the 0th finger number to the 1st finger number. By referring to 100 finger usage counts 902, it is possible to know a fingering with a high usage count in the song of the example pronunciation information 901. The ROM 102 or the external storage device 105 stores a plurality of example pronunciation information 901 of different songs. Note that the finger information 425 of the plurality of note information 411 constituting the chord may be “None”. In this embodiment, in steps S302 and S304 in FIG. 3, for each fingering from the finger number 425 of the previous note to the finger number 425 of the current note, the pronunciation of the notes of the model pronunciation information 901 and the performance pronunciation information 402 is generated. Timing deviation and / or velocity deviation is detected.

  In FIG. 3, in step S301, as in the first and second embodiments, the CPU 101 compares the note information 411 of the model pronunciation information 901 and the key press information 412 of the performance pronunciation information 402, and both steps. The deviation of the time (note generation timing) 422 is accumulated, and a total histogram is generated as shown in FIG.

  Next, in step S <b> 302, the CPU 101 presses the note information 411 of the model pronunciation information 901 and the key press information of the performance pronunciation information 402 for each fingering from the finger number 425 of the previous note to the finger number 425 of the current note. 412 and the difference between both step times (note generation timings) 422 is accumulated, and 100 histograms are generated as shown in FIG.

  Next, in step S303, as in the first and second embodiments, the CPU 101 compares the note information 411 of the model pronunciation information 901 and the key press information 412 of the performance pronunciation information 402, and determines the velocity ( (Key pressing speed) 424 is accumulated, and a total histogram is generated as shown in FIG.

  Next, in step S304, for each fingering from the finger number 425 of the previous note to the finger number 425 of the current note, the CPU 101 presses the note information 411 of the model pronunciation information 901 and the key press information of the performance pronunciation information 402. 412 and the difference of the velocity (key pressing speed) 424 is accumulated, and 100 histograms are generated as shown in FIG.

  Further, in step S216 in FIG. 2, the CPU (performance evaluation output unit) 101 performs fingering performance evaluation in accordance with the difference in fingering from the finger number 425 of the previous note to the finger number 425 of the current note. Is displayed (output) on the liquid crystal display 104. For example, the CPU 101 displays, for example, “weak point: left hand ring finger → left hand little finger”. Further, the CPU 101 may display performance evaluations similar to those in the first and second embodiments. According to this embodiment, the evaluation regarding fingering of performance can be obtained by outputting the performance evaluation of fingering.

  In FIG. 8, in step S <b> 802, the CPU 101 detects the fingering of the weak point having the lowest performance evaluation evaluated by the performance evaluation process. Next, in step S <b> 803, the CPU 101 refers to the finger usage count 902 of the example pronunciation information 901, and from the example pronunciation information 901 of a plurality of songs, the CPU 101 has the highest number of fingerings detected above. Search for a song. Next, in step S804, the CPU 101 displays (outputs) the searched tune as the practice tune suitable for the weak fingering practice on the liquid crystal display 104. For example, the CPU 101 displays “weak point: left-hand ring finger → left-hand little finger” and “next song: practice the fifth song”. That is, the CPU (performance evaluation output unit) 101 can output information on the practice music corresponding to the fingering with the largest difference in sound generation timing and / or velocity. Since the performer can receive the presentation of the music suitable for the fingering practice of the weak point, the player can practice the fingering effectively.

  In the first to third embodiments, an example of an electronic keyboard musical instrument is shown as an example of an electronic musical instrument. However, the electronic keyboard musical instrument is not limited to an electronic keyboard musical instrument, and other electronic stringed musical instruments that can perform fingering performances. It can also be applied to electronic musical instruments.

(Fourth embodiment)
FIG. 11 is a block diagram showing a configuration example of a performance evaluation apparatus according to the fourth embodiment of the present invention. The performance evaluation apparatus of this embodiment is configured by a computer such as a personal computer. When the computer executes the program, the performance evaluation apparatus according to the first to third embodiments can be realized. A CPU 1112, ROM 1113, RAM 1114, communication interface 1115, input device 1116, output device 1117, and external storage device 1118 are connected to the bus 1111. The CPU 1112 performs processing or calculation of data and controls various components connected via the bus 1111 and executes processing of the performance evaluation apparatus of the first to third embodiments. The ROM 1113 stores a control procedure (computer program) of the CPU 1112 in advance, and the computer is started when the CPU 1112 executes the computer program. A computer program is stored in the external storage device 1118, and the computer program is copied to the RAM 1114 and executed by the CPU 1112. The RAM 1114 is used as a work memory for processing data and a temporary storage for controlling each component. The communication interface 1115 is a communication interface for connecting to the electronic musical instrument of FIG. The input device 1116 is, for example, a keyboard and a mouse, and corresponds to the panel 111 in FIG. 1 and can perform various designations or inputs. The output device 1117 is a display, and corresponds to the liquid crystal display 104 of FIG. 1 and can display performance evaluation results and the next practice music. The external storage device 1118 is, for example, a hard disk storage device, a CD-ROM, or a flexible disk storage device, and the stored content does not disappear even when the power is turned off. The external storage device 1118 can store model pronunciation information and performance pronunciation information in addition to the above computer program.

  In the present embodiment, the processing in step S201 in FIG. 2 is performed by the electronic musical instrument in FIG. As a result, the performance pronunciation information 402 shown in FIG. 4B is generated. The performance evaluation apparatus in FIG. 11 reads out the performance sound generation information 402 generated by the electronic musical instrument using the external storage device 1118 or the communication interface 1115. Further, the performance evaluation apparatus in FIG. 11 reads out the example pronunciation information 401, 711, or 901 prepared in advance using the external storage device 1118 or the communication interface 1115. After that, the performance evaluation apparatus in FIG. 11 performs processes other than step S201 in the first to third embodiments by executing the program. The performance evaluation apparatus shown in FIG. 11 can perform performance evaluation on the performance pronunciation information 402 if the performer prepares only the performance pronunciation information 402. As described above, the performance evaluation apparatus may be configured with an electronic musical instrument as shown in FIG. 1 or a computer as shown in FIG.

  This embodiment can be realized by the computer of FIG. 11 executing a program. Further, a computer-readable recording medium in which the above program is recorded and a computer program product such as the above program can also be applied as an embodiment of the present invention. As the recording medium, for example, a flexible disk, a hard disk, an optical disk, a magneto-optical disk, a CD-ROM, a magnetic tape, a nonvolatile memory card, a ROM, or the like can be used.

  The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner. That is, the present invention can be implemented in various forms without departing from the technical idea or the main features thereof.

101 CPU
102 ROM
103 RAM
104 Liquid crystal display 105 External storage medium 106 External input / output interface 107 Bus 108 Key scan circuit 109 Keyboard 110 Panel scan circuit 111 Panel 112 Music sound generation unit 113 D / A conversion unit 114 Analog signal processing unit 115 Amplifier 116 Speaker 401 Model sound generation Information 402 Performance pronunciation information 411 Note information 412 Key press information 421 Key number 422 Step time 423 Gate time 424 Velocity 425 Finger number

Claims (7)

A storage unit for storing example pronunciation information including note information that associates a note with a finger number to play the note;
A detection unit that compares the played pronunciation information and the example pronunciation information that is played, and detects a deviation in pronunciation timing and / or velocity in both notes for each finger number;
A performance evaluation apparatus comprising: an output unit that outputs a performance evaluation of a finger corresponding to the finger number in accordance with a deviation for each finger number detected by the detection unit. The model pronunciation information has note information including a sound generation timing and velocity of the note and a finger number to play the note,
2. The performance evaluation apparatus according to claim 1, wherein the performance pronunciation information includes note information including a sound generation timing and velocity of the notes.   The performance evaluation apparatus according to claim 1, wherein the output unit outputs information on a practice song corresponding to the finger number having the largest deviation. The detection unit detects a deviation in sound generation timing and / or velocity deviation between the two notes for each fingering from the finger number of the previous note to the finger number of the current note,
The performance evaluation apparatus according to claim 1, wherein the output unit outputs a performance evaluation of the fingering according to a shift for each fingering detected by the detection unit.   The performance evaluation apparatus according to claim 4, wherein the output unit outputs information on a practice song corresponding to the fingering having the largest deviation. The performance evaluation apparatus according to any one of claims 1 to 5,
A performance controller for performing,
An electronic musical instrument comprising: a recording unit that records the performance pronunciation information in accordance with a performance operation of the performance operator. A reading step of reading example pronunciation information including note information in which notes and finger numbers to which the notes should be played are associated;
A detection step of comparing the played pronunciation information played with the example pronunciation information and detecting a difference in sound generation timing and / or velocity of both notes for each finger number;
A program for causing a computer to execute an output step of outputting a performance evaluation of a finger corresponding to the finger number in accordance with the detected deviation for each finger number.

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