JP2518341B2 - Automatic playing device - Google Patents

Description

Detailed Description of the Invention

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic performance device for writing performance data in a memory and reading performance data in the memory for automatic performance, and more particularly to an automatic performance device with improved ending processing. "Prior Art" As one of the conventional automatic performance devices, Japanese Patent Application Laid-Open No. 53-70421
An "automatic accompaniment device" disclosed in Japanese Patent Publication is known. In this device, when a control switch (stop switch) is operated during ending, the rhythm pattern changes to a finale pattern, and the automatic performance ends when the finale pattern ends. [Problems to be Solved by the Invention] By the way, in the automatic performance device, when the automatic performance is ended or the performance data recording is ended, the stop switch is operated rather than being ended when the stop switch is operated. It is preferable to end at the timing of the first bar line after the start. Further, it is desirable that the automatic performance can be easily resumed when the automatic performance is finished. It is an object of the present invention to provide an automatic performance device that can meet all of the above requirements. "Means for Solving the Problem" The first invention comprises a performance data memory in which the performance data is stored, and an automatic performance means for reading the performance data in the performance data memory and automatically performing the performance. In the automatic performance device, an operation switch for instructing stop or start of the automatic performance, operation detection means for detecting operation of the operation switch, and operation storage means for storing that the operation switch is operated Writing means for writing to the operation storing means that the operation switch has been operated by the operation detecting means during automatic performance, bar detecting means for detecting bar line timing during automatic performance, and automatic performance during automatic performance. A discriminating means for discriminating whether or not the operation switch stored in the operation storage means is operated when the bar line timing is detected by the bar detecting means. And a stop control means for stopping the automatic performance when the operation switch is operated by the determining means, and the operation detection while the automatic performance is stopped by the stop control means. When the operation of the operation switch is detected by the means, a restart control means for restarting the stopped automatic performance is provided. A second invention is a performance data memory for storing performance data, an input means for inputting the performance data, and a writing means for writing the performance data input by the input means in the performance data memory. An automatic performance device comprising automatic performance means for reading out performance data from the performance data memory and automatically performing the performance, and detecting an operation switch for instructing stop or start of writing of the performance data and operation of the operation switch. The operation detecting means, the operation storing means for storing that the operation of the operation switch is performed, and the operation storing means indicating that the operation switch is operated by the operation detecting means during writing of performance data. A writing means for writing to, and a bar detecting means for detecting bar line timing during writing of performance data,
A discriminating means for discriminating whether or not the operation switch stored in the operation storing means is operated when the bar detecting means detects the bar line timing during writing of performance data, and the operating switch is operated by the discriminating means. And a stop control means for stopping the writing of the performance data when it is determined that the operation has been performed. [Operation] According to the present invention, when the operation switch is operated during the automatic performance or the writing of the performance data, the automatic performance or the data writing is stopped at the timing of the next bar line. When the operation switch is operated again after the automatic performance is stopped, the automatic performance is restarted. [Embodiment] An embodiment of the present invention will be described below with reference to the drawings.

【Constitution】

FIG. 1 is a block diagram showing the configuration of an electronic musical instrument to which the automatic musical instrument according to the embodiment is applied. This electronic musical instrument includes a keyboard 10 and an operation panel 20. The keyboard 10 is composed of a plurality of keys for designating musical tones, and the depression and release of each key is detected by opening and closing a plurality of key switches provided for each key in the key switch circuit 10a. . In addition, key touch detection circuit
Key touch sensors provided for each key in 10b also operate, and these key touch sensors detect initial key touches such as key pressing speed and key pressing pressure of each key. It has become. The key switch circuit 10a and the key touch detection circuit 10b are connected to the bus 30. The operation panel 20 has 8 beats as shown in FIG.
Rhythm selection switch to select rhythm type such as samba
22, a tone selection switch 23 for selecting a tone such as a piano or a flute, a master volume 24 for adjusting the volume of the generated tone, a tempo volume 25 for adjusting the tempo of the generated tone, and a memory area are designated. Track switches 26a and 26b, LEDs (light emitting diodes) 27a and 27b provided above the track switches 26a and 26b, a start switch 28 for instructing the start of automatic performance or the start of recording of performance data, and the start switch LED 29 provided above 28, a stop / continue switch 30 for instructing to stop automatic performance or stop recording of performance data, and instructing to resume the stopped automatic performance, and instructing to erase performance data in the memory. And a delete switch 31 are provided. The operation switch circuit 20a encodes the output of each of these switches and outputs it to the bus 30. The display control circuit 20b controls lighting of the LEDs 27a, 27b, 29. Further, to the bus 30, a tempo oscillator 40, a rhythm sound signal generating circuit 51, a musical sound signal generating circuit 52 for a keyboard, a musical sound signal generating circuit 53 for automatic performance, a data storage circuit 60, and a microcomputer 70 are connected. The tempo oscillator 40 transmits a tempo clock as a rhythm interrupt signal via the bus 30 to the microcomputer 70 according to the set tempo.
Output to. The rhythm sound signal generating circuit 51 has a plurality of percussion sound signal forming circuits for forming percussion sound signals corresponding to percussion instruments such as cymbals, bass drums, etc.
The percussion instrument sound signal is formed and output according to the rhythm pattern data supplied from 70 via the bus 30. The keyboard tone signal generation circuit 52 and the automatic performance tone signal generation circuit 53 each have a plurality of tone signal formation channels for forming tone signals corresponding to musical instruments such as piano and violin. Generates and outputs a musical tone signal based on performance data supplied from the microcomputer 70 via the bus 30 in response to key depression and release on the keyboard 10, operation of the tone color selection switch 23 and operation of the rhythm selection switch 22. The automatic performance tone signal generating circuit 53 is stored in the data storage circuit 60, is read by the microcomputer 70, and forms and outputs a tone signal based on the automatic performance data supplied through the bus 30. The tone signals from the rhythm tone signal generating circuit 51, the keyboard tone signal generating circuit 52 and the automatic performance tone signal generating circuit 53 are mixed and supplied to the amplifier 54. The output of the amplifier 54 is connected to the speaker 55.
A tone corresponding to the tone signal supplied from the speaker is generated. The data storage circuit 60 includes a rhythm pattern data memory 61, a performance data memory 62, and a buffer register 63 connected to the bus 30, respectively. Rhythm pattern data memory 61
Is composed of a ROM, and stores rhythm pattern data instructing the formation and output of each percussion instrument sound signal in the rhythm sound signal generation circuit 51 in a time series over one bar length for each rhythm type. The performance data memory 62 is composed of a RAM, and as shown in FIG.
And a head data area HDE. And
In the head data area HDE, the head address H of the area I
EADAD (I) and the start address HEADAD (I
I) is memorized. In addition, areas I and II include a number of storage locations A addressed by an address ADR described later.
Has PM (ADR). The following various types of automatic performance data are stored in each storage position APM (ADR) in the data format shown in FIG. Timing data: Consists of an identification mark indicating timing data, and time data TIMD indicating an elapsed time from the beginning of a bar. Key press data: Consists of an identification mark indicating key press event data on the keyboard 10, a key code KC indicating a pressed key, and touch data KTD indicating an initial key touch (volume level). Key release data: An identification mark indicating key release event data on the keyboard 10 and a key code KC representing a released key. Tone data: Tone data indicating the tone selected by the tone selection switch 23, and an identification mark indicating the tone data. Bar chord: Indicates that the progress timing of the automatic performance is a timing corresponding to the bar line. End code: Indicates the end timing of the automatic performance. The microcomputer 70 includes a program memory 71, a CPU 72, and a working memory 73 connected to the bus 30, respectively. The program memory 71 is composed of a ROM and stores a main program, a rhythm interrupt program, and their subprograms. The CPU 72 starts the execution of the main program by turning on the power switch (not shown), and repeatedly executes the program until the power switch is turned off. When the tempo clock from the tempo oscillator 40 arrives, the execution of the main program is interrupted. Executes the rhythm interrupt program as an interrupt. The working memory 73 is composed of RAM, and temporarily stores a plurality of data and flags necessary for executing the program. The main ones of these data and flags are listed below. ◇ Rhythm run flag RUN ・ ・ ・ When this flag RUN is set to “1”, a rhythm sound is generated, and when set to “0”, the rhythm sound is stopped. ◇ Play flag PLY1, PLY2 ... When the flag PLY1 is set to "1", the automatic performance is possible based on the performance data in the area I of the performance data memory 62. Set this flag PLY1 to "1"
Then, when the start switch 28 is pressed, the automatic performance is started. Similarly, when the flag PLY2 is set to "1", an automatic performance is enabled based on the performance data in the area II. ◇ Record flag REC1, REC2 ... When the flag REC1 is set to "1", the data writing in the area I of the performance data memory 62 becomes possible. When the start switch 28 is pressed or the key of the keyboard 10 is turned on after setting the flag REC1 to "1", the writing of the area I is started. Similarly, when the flag REC2 is set to "1", the area II is ready for data writing. ◇ Synchronous start flag SST ... When this flag SST is set to "1", the rhythm sound starts at the same time when the keyboard key is operated at the start of writing the performance data. That is, it is possible to start the rhythm sound synchronously. ◇ Record check flags DTARI1, DTARI2 ... When performance data is written in area I of the performance data memory 62,
When the flag DTARI1 is set to "1" and the performance data is written in the area II, the flag DTARI2 is set to "1". ◇ Stop reserve flag SRF: If this flag SRF is set to "1" during automatic performance, the automatic performance will stop at the timing of the next bar line. Further, when this flag SRF is set to "1" at the time of writing data, an end code is written in the performance data memory 62 at the timing of the next bar line, and the data writing ends. Address data ADR1, ADR2 ... Both of these address data are output to the address terminal of the performance data memory 62. The address data ADR1 is used to address the area I, and the address data ADR2 is used to address the area II. Is specified. ◇ Mode data M1, M2... Each time the track switch 26a is pressed, the mode data M1 circulates and changes in the order of 1 → 2 → 0 → 1 →. The operation mode is determined as follows according to the mode data M1. 1 ... Area I automatic performance mode, 2 ... Area I data write mode 0 ... Normal performance mode Similarly, the mode data M2 circulates and changes every time the track switch 26b is pressed. The operation mode is determined according to the mode data M2 as follows: 1 ... Area II automatic performance mode, 2 ... Area II data write mode 0 ... Normal performance mode ◇ Tempo count data TCNT: Tempo oscillator 40 The data is incremented each time the tempo clock signal is output, and is reset to "0" when it reaches "48". That is, this tempo count data TCNT is
The tempo clock signal is repeatedly counted between "0" to "47". This tempo count data TCNT indicates the progress timing of one measure, and this data TCNT is "48".
When (= 0), there is bar line timing. ◇ Read data RDDT1, RDDT2 ・ ・ ・ Read data RDDT1
Is data read from area I of the performance data memory 62, and read data RDDT2 is data read from area II. ◇ Read timing data RDTIM1, RDTIM2 ... Read timing data RDTIM1 is the timing data in the data read from area I, and read timing data RDTIM2 is the timing data in the data read from area II. is there.

【motion】

Next, the operation of the electronic musical instrument having the above configuration will be described with reference to FIGS.
This will be described with reference to the flowchart shown in the figure. (1) Normal performance mode When the track switches 26a and 26b are operated to turn off the LEDs 27a and 27b, the normal performance mode is set. In this mode, the electronic musical instrument performs its normal playing function. That is, first, when a power switch (not shown) is turned on, the CPU 72 starts executing the main program in step 100 of FIG. 5, and clears the registers and flags in the working memory 73 in step 101. Thus, the microcomputer 70 is set to the initial state.
After this initial setting, in step 102, the CPU 72 scans each key switch in the key switch circuit 10a and each operation switch in the operator switch circuit 20a, and thereby presses and releases key information about the keyboard 10 and each operation panel 20. The operation information of the switch is read through the bus 30, and in the step 103, a key release event on the keyboard 10 or an operation event on the operation panel 20 is detected by using the working memory 73 based on the read key release information and operation information. Detect the presence or absence. now,
If no key is depressed and released on the keyboard 10 and no operation is operated on the operation panel 20, the CP
U72 determines "NO" in step 103, that is, no event, and returns the program to step 102.
The circulation process consisting of 2,103 is continuously executed. Next, when the track switch 26a is pressed by the player, the result of the determination at step 103 becomes "YES", and the routine proceeds to step 104. In step 104, the type of the event is determined. In this case, since it is the on event of the track switch 26a, the process proceeds to step 107. FIG. 6 is a flowchart of the process in step 107. First, in step 150, the mode data M1 is incremented. Next, proceeding to step 151, it is determined whether or not the mode data M1 is "1". If the result of this determination is "YES", the flow proceeds to step 152, where "N
If “O”, the process proceeds to step 154. At step 152, it is determined whether or not the record check flag DTARI1 is "1". If the result of this determination is “YES”, step 1
Proceed to 53 and return to step 150 if "NO". In step 153, “1” is set in the play flag PLY1 and “0” is set in the record flag REC1, and the LED 27a
Lights up in green. Then, the process proceeds to step 154. In step 154, it is determined whether the mode data M1 is "2". If the result of this determination is “YES”, the operation proceeds to step 155, and if “NO”, the operation proceeds to step 157. In step 155, it is determined whether the mode data M2 is "2". If the result of this determination is “YES”, step 1
Returning to step 50, if "NO", proceed to step 156. In step 156, the play flag PLY1 is set to "0", the record flag REC1 and the sync start flag SST are each set to "1", and the LED 27a is lit in red. And
Proceed to step 157. In step 157, the mode data M1
Is determined to be “3”. If the determination is "NO", the process returns to step 102 of FIG. 5, and if "YES", the process proceeds to step 158. In step 158, the mode data M1 is set to "0", the play flag PLY1, the record flag REC1, and the sync start flag SST are cleared, and the LED 27a is turned off. And step
Return to 102. As is clear from the above processing, the track switch 26
Each time a is pressed, the mode data M1 is incremented (step 150). When the mode data M1 becomes "3", it is returned to "0" in step 158. That is, each time the track switch 26a is pressed, the mode data M1
Sequentially changes from 0 → 1 → 2 → 0 → .... Further, according to the value of the mode data M1, setting of a flag and turning on / off of the LED 27a are performed (steps 153, 156, 158), and the operation mode is determined. However, if the performance data has not yet been written to the area I of the memory 62 when the mode data M1 is "1" (automatic performance mode), the determination result of step 152 is "NO", and Then, the mode data M1 becomes "2". That is, when the performance data is not written in the area I, the mode data M1 is "0".
From "1" to "2" by jumping, so that the mode data M1 cannot be set to "1". When the mode data M1 is "2" (data write mode) and the mode data M2 set by the track switch 26b is already "2", the determination result of step 155 is "YES". Next step
Returning to 150, the mode data M1 is incremented again. That is, when the mode data M2 is "2", the mode data M1 cannot be set to "2". This is to prevent duplicate writing of the same data in areas I and II. The above is the description of the CPU 72 when the track switch 26a is operated.
Processing. On the other hand, when the track switch 26b is operated, the process proceeds from step 104 to step 108 in FIG. FIG. 7 shows the processing of step 108. Note that this processing is exactly the same as the processing in FIG. 6 described above (however, M1
→ Subscript 1 becomes 2 as in M2), and the description is omitted. By operating the track switches 26a and 26b, the LED
If both 27a and 27b are turned off, the play flags PLY1 and PL
Y2 and record flags REC1 and REC2 are both "0" (6th
Step 158 in the figure and step 168 in FIG. 7), the normal performance mode is set. In this mode, the performer
When a performance is performed using the operation panel 10 and the operation panel 20, the musical sound is generated from the speaker 55. That is, first, when the key of the keyboard 10 is turned on, the judgment result of step 103 in FIG. FIG. 8 is a flowchart of this key / tone color event routine. First, at step 200, simultaneously generated event data is fetched into the event buffer register 63. That is, in this case, key press data (see FIG. 4) including the key code KC of the turned-on key, the key touch data KTD and the identification mark is fetched into the event buffer register 63. Next, in step 201, the event data in the event buffer register 63 is output to the keyboard musical tone signal generating circuit 52. in this case,
The key depression data in the event buffer register 63 is output to the keyboard tone signal generation circuit 52. Thereby, a musical sound of the key turned on is generated. Next, proceeding to step 202, it is determined whether the record flag REC1 or REC2 is "1". In this case, the judgment result is “NO” and the step
Proceed to 203. In step 203, the event buffer register 63 is cleared. Then, the process returns to step 102 in FIG. Next, when the key of the keyboard 10 is turned off, similarly to the above, the step 20 is executed through the steps 103 to 104.
Proceed to 0 (FIG. 8), and the key code KC of the turned off key
The key release data including the identification mark and the identification mark is taken into the event buffer register 63, and then output to the keyboard tone signal generation circuit 52 in step 201. As a result, the musical sound of the turned off key stops. Next, the process returns to step 102 via steps 202 and 203. Next, when the timbre selection switch 23 is operated, in step 200, data indicating the operated switch is written in the event buffer register 63, and then in step 201, the same data is stored in the keyboard tone signal generation circuit 5.
Output to 2. Thus, the tone corresponding to the operated tone color selection switch is set in the keyboard tone signal generation circuit 52. Similarly, when the master volume 24 is operated, data indicating the operation amount of the master volume 24 is set in the keyboard tone signal generation circuit 52, thereby changing the volume of the tone. Next, when generating a rhythm sound, the start switch 28 is pressed. When the start switch 28 is pressed, the result of the determination in step 103 becomes “YES”, and the processing proceeds to the start processing routine of step 109 via step 104. FIG. 9 is a flow chart showing this start processing routine. First, in step 251, it is judged whether or not the play flag PLY1 or PLY2 is "1". In this case, the judgment result is "NO". Continue to 252. Step 2
At 52, it is determined whether or not the record flag REC1 is "1".
In this case, the determination result is “NO”, and the process proceeds to step 253. In step 253, it is determined whether or not the record flag REC2 is "1". In this case, since the determination result is "NO", the process proceeds to step 254. In step 254, the rhythm run flag RUN is set to "1", and the tempo count data TCNT is cleared. And step 102
(FIG. 5). Thus, when the start switch 28 is pressed in the normal performance mode, the rhythm run flag RUN is set to "1" and the tempo count data TCNT is cleared. Then, when the flag RUN is set to “1”, a rhythm sound is formed based on the tempo clock output from the tempo oscillator 40 and is thereafter emitted. That is, when the tempo clock is output from the tempo oscillator 40, the CPU 72 is interrupted and the processing of the CPU 72 is performed by the tenth clock.
It proceeds to the rhythm interrupt processing routine shown in the figure. In this routine, first, in step 300, it is determined whether or not the record flag REC1 or REC2 is “1” and the sync start flag SST is “1”. Then, in this case, since the determination result is “NO”, step 301
Proceed to. In step 301, the rhythm run flag RUN is "1"
It is determined whether or not. If the result of this determination is "NO", the process returns to the main routine of FIG. 5, but if "YES", the process proceeds to step 302. In step 302, rhythm pattern data is read from the rhythm pattern data memory 61 based on the data indicating the rhythm type currently set in the working memory 73 and the tempo count data TCNT, and the read rhythm pattern data is read out. Output to rhythm sound signal generation circuit 51. Each percussion instrument sound signal forming circuit in the rhythm sound signal generating circuit 51 is driven based on the rhythm pattern data, thereby generating a rhythm sound. Next, proceeding to step 303, it is determined whether or not the play flag PLY1 or PLY2 is "1". And in this case,
Since the result of the determination is “NO”, the operation proceeds to step 304. In step 304, the tempo count data TCNT is incremented. Then, in step 305,
It is determined whether the tempo count data TCNT has a bar end value “48”. And in this case, the judgment result is "NO".
Therefore, the procedure returns to the main routine. Thereafter, every time a tempo clock is generated, the above-described step 302 is executed to generate a rhythm sound, and step 304 is executed to increment the tempo count data TCNT. When the tempo count data TCNT becomes “48”, the result of the determination in step 305 becomes “YES”, and the flow proceeds to step 306. In step 306, it is determined whether the record flag REC1 or REC2 is "1". In this case, the determination result is “NO”, and the flow proceeds to step 307. In step 307, it is determined whether or not the stop reserve flag SRF is "1". In this case, the judgment result is “NO”,
Go to step 308. In step 308, the tempo count data TCNT is cleared. Then, the process returns to the main routine. The above is the process of rhythm sound generation. Next, in this normal performance mode, to stop the rhythm sound, the stop / continue switch 30 is pressed. This stop /
When the continue switch 30 is pressed, step 103
Then, the process proceeds to the stop / continue processing routine of step 110 through step 104. FIG. 11 is a flowchart of this routine. First, in step 401,
It is determined whether the play flag PLY1 or PLY2 is "1",
In this case, the judgment result is "NO", so
Continue to 402. In step 402, it is determined whether the record flag REC1 or REC2 is "1". If the result of this determination is “NO”, the operation proceeds to step 403. In step 403, the rhythm run flag RUN is reset. When the rhythm run flag RUN is reset, step 302 in FIG. 10 is no longer executed, and the rhythm sound stops. Then, the process returns to the main routine. Next, when the rhythm selection switch 22 is operated, the process proceeds from step 103 to step 106 via step 104. In this step 106, data indicating the rhythm type is set in the working memory 73 corresponding to the operated rhythm selection switch 22. Thereafter, reading from the rhythm pattern data memory 61 is performed based on the set data. Also, when the tempo volume 25 is operated, the process proceeds to step 106, and the oscillation frequency of the tempo oscillator 40 is set according to the operation amount of the tempo volume 25. (2) Data writing mode This mode is used in area I of performance data memory 62 or
II is a mode for writing performance data. When writing performance data in area I, first, use the track switch 26
The LED 27b is turned off by b, and then the LED 27a is turned on by the track switch 26a. When a performance is performed using the keyboard 10 and the operation panel 20, performance data corresponding to the performance is sequentially written in the area I. There are two ways to start.
One is to not operate the start switch 28,
In this case, the data writing and the generation of the rhythm sound are started at the same time when the keyboard keys are first operated. Another one
One is a method of operating the start switch 28. In this case, the data writing and the generation of the rhythm sound are started at the same time when the start switch 28 is pressed. When writing performance data in the area II, first, the LED 27a is turned off by the track switch 26a, and then the LED 27b is turned on by the track switch 26b. Then, the performance is performed using the keyboard 10 and the operation panel 20. Hereinafter, processing of the CPU 72 in the data write mode will be described. First, when the track switch 26b is operated and the LED 27b is turned off, the mode data M2 becomes "0", the play flag PLY2, the record flag REC2, as apparent from step 168 of FIG. Sync start flag
SST is set to "0". Next, when the track switch 26a is operated and the LED 27a is turned on in red, the step shown in FIG.
As is clear from 154 and 156, the mode data M1 is “2”.
And the play flag PLY1 is set to “0” and the record flag
REC1 is set to "1", and the sync start flag SST is set to "1". Record flag REC1 and synchronized start flag SS
When both T are set to "1", a metronome sound is generated at quarter note timing thereafter to inform the player of the tempo. That is, when the tempo clock is output from the tempo oscillator 40 and the processing of the CPU 72 proceeds to the interrupt processing of FIG. 10, first, the determination of step 300 is made. And
In this case, since the determination result is “YES”, the process proceeds to step 320. In step 320, the rhythm pattern of the metronome sound is read from the rhythm pattern memory 61 at each quarter note timing, and output to the rhythm sound signal generation circuit 51. As a result, a metronome sound is generated at quarter note timing. Next, when the keyboard keys are operated, step 103 (fifth
The determination result in FIG. 8 is “YES”, and the process proceeds to the key / tone color event routine in FIG. In this routine, first, the processing of steps 200 and 201 is performed, thereby generating a musical sound of the operated key. Next, the process proceeds to step 202, and in this case, the determination result is “YES”, so the process proceeds to step 204. In step 204, it is determined whether or not the sync start flag SST is "1". In this case, the determination result is “YES”, and the routine proceeds to step 205. In step 205, the synchro start flag SST is set to "0", the rhythm run flag RUN is set to "1", and the tempo count data TCNT is cleared.
When the sync start flag SST becomes "0", the metronome sound stops thereafter, and when the rhythm run flag RUN is set to "1", a rhythm sound is generated thereafter. Next, proceeding to step 206, the record flag REC1 is set to "1".
It is determined whether or not. Then, in this case, since the determination result is “YES”, the process proceeds to step 207. Step
In 207, the record check flag DTARI1 is set to "1", and the head address data HEADAD (I) third
Is set as address data ADR1. Then, it proceeds to step 209. If the result of the determination in step 206 is “NO”, that is, the record flag REC2 is “1”.
If (in case of writing in area II), the process proceeds to step 208, the record check flag DTARI2 is set to "1", and the head address data HEADAD (II) is set as address data ADR1. Next, at step 209, the timing data (see FIG. 4) composed of the identification mark and the time data TIMD is stored in the storage location of the memory 62 indicated by the address data ADR1.
Write to APM (ADR1). Here, tempo count data TCNT is set as time data TIMD. Therefore, it is "0" at this point (see step 205). Next, in step 210, the address data ARR
1 is incremented. Next, when proceeding to step 211,
The first event data in the event buffer register 63 is read out, attached with an identification mark, and written to the storage location APM (ADR1) of the memory 62. Next, proceeding to step 212,
The first event data in the event buffer register 63 is cleared. Next, in step 213, it is determined whether or not there is event data in the event buffer register 63. And this judgment result is "YE
In the case of "S", the processing of steps 210 to 212 is performed again. On the other hand, if the decision result in the step 213 is “NO”,
In step 214, the address data AR1 is incremented, and then in step 215, the record flag R
It is determined whether EC1 is "1". If the result of this determination is “YES”, the operation proceeds to step 216. In step 216, it is determined whether the address data ADR1 is the final address of area I or not. Then, if this determination result is "NO", the process returns to step 102 (Fig. 5), and if "YES", the process proceeds to step 217. In step 217, the record flag REC1
Is reset, the LED 27a is turned off, and the end code is written in the storage position APM (ADR1) of the memory 62. Then, the process returns to step 102. On the other hand, when the determination result of step 215 is “NO”, that is, the record flag REC2 is “1”.
In the case of, the determination of step 218 is performed, and when the determination result is "YES", the processing of step 219 is performed. As described above, when the mode data M1 is set to "2" and M2 is set to "0" and the keyboard key is operated, the rhythm run flag RUN is set to "1" (step 205). Is started, and the event data related to the operated key is written to the area I. Thereafter, each time a keyboard key is operated or switches of the operation panel 20 are operated, the above-described steps 209 to 213 are performed.
Is executed and performance data is written in area I. Also, at the bar timing, the determination result of step 305 in FIG. 10 is “YES”, and the process proceeds to step 306. In this case, the determination result of step 306 is “YES”, so that the process proceeds to step 309. move on. In step 309,
The measure code is stored in the performance data memory 62 at the storage location APM (ADR
1), and then the address data ADR1 is incremented. Next, when the address data ADR1 reaches the final address of the area I, step 217 is executed and the data write mode ends. To end the data writing before that, the stop / continue switch 30 is pressed. When the switch 30 is pressed, the process proceeds to the stop / continue process of FIG. 11, steps 401 and 402 are sequentially executed, and the process proceeds to step 404. In step 404, it is determined whether the rhythm run flag RUN is "0". In this case, the determination result is “NO”, and the process proceeds to step 405. Step 4
At 05, the stop reserve flag SRF is set to "1". Then, the process returns to the main routine. When the stop reserve flag SRF becomes "1", the determination result of step 310 (FIG. 10) is "YES" at the timing of the next bar line.
And proceed to step 311. In step 311, the end code is written to the storage location APM (ADR1) of the memory 62. Next, when proceeding to step 312, the stop reserve flag SRF and the rhythm run flag RN are reset and the LED 29 is turned off. Next, the routine proceeds to step 308, where the tempo count data TCNT is cleared, and the routine returns to the main routine. The above is the process of writing performance data. In the above process, after the mode is set, the data writing and the generation of the rhythm sound are started by pressing the keyboard key. However, after the mode is set, the data writing and the generation of the rhythm sound are started by pressing the start switch 28. You may start. That is, for example, when the start switch 28 is pressed after setting the mode data M1 to "2" (M2 is "0"), the determinations in steps 251, 252 of FIG. 9 are sequentially performed, and the process proceeds to step 255. In step 255, head address data HEADAD (I) is set as address data ADR1. Next, when proceeding to step 256, the tempo count data TCNT is cleared, the rhythm run flag RUN is set, the sync start flag SST is reset, and the LED 29 is turned on. Then steps 257,258
And returns to the main routine. In this way, after setting the mode data M1 to "2",
When the start switch 28 is pressed, the address data ADR1 is set to the head address of the area I, and the rhythm run flag RUN is set to "1" to start generating a rhythm sound. Thereafter, when a performance is performed by operating the keyboard keys, performance data is sequentially written into the area I in the same manner as described above. The case of writing in area I has been described above as an example, but the same applies to the case of writing in area II. Next, when it is desired to erase all data in the area I or the area II, the delete switch 31 in FIG. 2 is pressed. When the delete switch 31 is pressed, the determination result of step 103 becomes “YES”, and
Proceeding to 1, the data erasing process is performed. FIG. 12 is a flow chart of this data erasing process. First, when proceeding to step 451, it is judged whether or not the rhythm run flag RUN is "1". Then, if the result of this determination is "YES", the flow returns to step 102. That is, when a rhythm sound is generated, data cannot be deleted even if the delete switch 31 is pressed. On the other hand, if the decision result in the step 451 is “NO”, the process proceeds to a step 452. In step 452, it is determined whether the record flag REC1 is "1". Then, if this determination result is "YES", that is, if it is the data writing mode of the area I, the process proceeds to step 453, sets the record check flag DTARI1 to "0", and then returns to step 102. If the determination result of step 452 is “NO”, the process proceeds to step 454. In step 454, it is determined whether the record flag REC2 is "1". If the result of this determination is "YES", that is, if the mode is the data write mode for area II, the process proceeds to step 455, sets the record check flag DTARI2 to "0", and returns to step 102. If the result of the determination in step 454 is “NO”, that is, if the write mode is not in any of the areas I and II, the process returns to step 102 as it is. (3) Automatic performance mode In this mode, the performance data in the performance data memory 62 is read out, and an automatic performance is performed. When performing the automatic performance based on the performance data in the area I of the performance data memory 62, the mode data M2 is set to "0", M1 is set to "1", and the automatic performance is performed based on the performance data in the area II. Sets the mode data M1 to "0" and M2 to "1". Then, the start switch 28 is pressed. Hereinafter, the case where an automatic performance is performed based on the performance data in the area I will be described as an example. First, when the mode data M2 is set to "0", step 168 of FIG. 7 is executed. Next, when the mode data M1 is set to "1", the determination result of step 151 in FIG. 6 becomes "YES",
Proceed to step 152. At step 152, it is determined whether or not the record check flag DTARI1 is "1". If the determination result is "YES", that is, if the performance data is already written in the area I, step 15
Go to 3. In step 153, the play flag PY1 is set, the record flag REC1 is reset, and the LED2
7a is lit green. Next, when the start switch 28 is pressed, the process proceeds to step 251 in FIG. 9, and the play flag PLY1 or PLY2 is set to "1".
It is determined whether or not. Then, in this case, the determination result is “YES”, and the routine proceeds to step 259. In step 259, the head address data HE is used as the address data ADR1.
ADAD (I) and head address data HEADAD (II) are set as address data ADR2, respectively. next,
After the processing of step 256 is performed, the routine proceeds to step 257, where it is determined whether or not the play flag PLY1 is "1". Then, in this case, since the determination result is “YES”, the process proceeds to step 260. In step 260, the address data AD
R1 {in this case, the data in the storage location APM (ADR1) of the memory 62 indicated by the head address data HEADAD (I)} is read and set as read timing data RDTIM1. Next, proceeding to step 258, it is determined whether or not the play flag PLY2 is "1". Then, in this case, since the determination result is “NO”, the process returns to step 102 (FIG. 5). If the determination result in step 258 is “YES”, that is, if the performance is automatic performance based on the performance data in area II, the process proceeds to step 261, and the data in the storage location APM (ADR2) indicated by the address data ADR2 is It is read and set as read timing data RDTIM2. In this way, the automatic performance mode of area I is set,
Then, when the start switch 28 is pressed, the play flag PLY1 is set, and then the rhythm run flag RUN is set. When these flags PLY1 and RUN are set, an automatic performance sound and a rhythm sound are thereafter generated based on the tempo clock output from the tempo oscillator 40. That is, when the tempo clock is generated, the CPU 72 is interrupted and the rhythm interrupt process of FIG. 10 is performed. In this case, first, the process proceeds to step 302 via steps 300 and 301, and a rhythm sound is generated. Next, the routine proceeds to step 303, where the judgment result is “YES”, so that the routine proceeds to the automatic performance data read routine 313. FIG. 13 shows the automatic performance data reading routine 31.
6 is a flowchart showing details of Step 3. This routine 313 is a read routine RI for reading the data in the area I of the memory 62.
And a read routine RII for reading data in the area II. The processing contents of the routines RI and R II are exactly the same, and only the flags or data are different. Upon proceeding to the routine 313, first, at step 501, it is determined whether or not the record check flag DTARI1 is "1". If the judgment result is "NO", that is, if there is no performance data in the area I, the routine R
Jump on I and go to routine R II. Also, step 5
If the determination result in 01 is “YES”, the process proceeds to step 502.
In step 502, it is determined whether the tempo count data TCNT is equal to the read timing data RDTIM1.
If the result of this determination is "NO", the routine RI
Exit to Routine R II. In the case of “YES”, the flow proceeds to step 503. In step 503, the address data
ADR1 is incremented. Next, the data in the storage location APM (ADR1) of the memory 62 is read and set as the read data RDDT1. Next, proceeding to step 504, it is determined whether or not the read data RDDT1 is a bar code. If the result of this determination is "YES", then step 5
Go to 05. At step 505, the value “47” obtained by subtracting “1” from the bar end value “48” is read timing data RD
Set as TIM1 and exit routine RI. On the other hand, if the determination result of step 504 is “NO”, the process proceeds to step 506. In step 506, it is determined whether or not the read data RDDT1 is timing data. If the result of this determination is “YES”, the operation proceeds to step 507, where the read data RDDT1 is set as read timing data RDTIM1. If the determination result of step 506 is “NO”, the process proceeds to step 508. In step 508, it is determined whether or not the read data RDDT1 is an end code. Then, if the result of this determination is “YES”, the flow proceeds to step 509. At step 509, tone generation end processing is performed. That is,
The key release data for instructing the stop of the currently sounding tone is output to the automatic performance tone signal generating circuit 53. This stops the musical sound. Next, in step 510, the play flag PLY1 is cleared, the LED 27a is turned off, and the rhythm run flag RUN is reset. And
Exit routine RI. If the determination result of step 508 is “NO”, the process proceeds to step 511. At step 511, the read data RDDT1 is converted to the tone signal generation circuit 5 for automatic performance.
Output to 3. Then, the process returns to step 503. In this way, when the routine proceeds to the automatic performance data reading routine 313, first, the routine proceeds to step 502 via step 501.
If the result of the determination in step 502 is "NO", the routine exits from the routine RI. That is, tempo count data T
Until the CNT matches the read timing data RDTIM1, no sound generation processing is performed. Then with the data TCNT
If RDTIM1 matches, the next performance data is read from area I (step 503). If the performance data is, for example, performance data of a key-on event, in step 511 the automatic performance tone signal generating circuit 5
3 to generate a musical tone. Next, the routine proceeds to step 503, where data reading is performed again. If the read data is timing data, the process of step 507 is performed. Thereafter, the tone generation process is not performed until the tempo count data TCNT matches the read timing data RDTIM1 set in step 507. And both data TCNT and RDTIM1
Is matched again, the same sound generation processing as above is performed,
By repeating this, automatic performance is performed. Next, when the data read from the area I is a bar code, the read timing data RDTIM1 is "47".
Is set to As a result, the tone generation process is not performed until the timing of the next bar line. Then, at the next bar line timing, data reading of area I is performed,
In this case, the timing data or bar code is read. If it is timing data, thereafter, data reading is not performed until the tempo count data TCNT matches the timing data, and if it is a bar code, data reading is performed for the next one bar. Not done. Next, when the data read from the area I is an end code, the processing of steps 509 and 510 is performed, whereby the automatic performance mode ends. The above is the processing of the routine RI, and an automatic performance based on the performance data in the area I is performed by this processing. On the other hand, the routine R II is a process for performing an automatic performance based on the performance data in the area II. Therefore, when only the routine RI is executed, a musical sound based on the performance data in the area I is generated, and when only the routine R II is executed, a musical sound based on the performance data in the area II is generated, and When both routines RI and R II are executed, musical tones based on the performance data in the areas I and II are simultaneously generated. Next, when the automatic performance is stopped during the automatic performance (before the end code is read), the stop / stop is performed.
Press the continue switch 30. When the stop / continue switch 30 is pressed, the step shown in FIG.
From 104, the process proceeds to step 401 in FIG. 11, and in this case, since the determination result of step 401 is “YES”, step 40
Go to 6. In step 406, it is determined whether the rhythm run flag RUN is "0". Then, in this case, since the determination result is “NO”, the flow proceeds to step 405, the step reserve flag SRF is set to “1”, and the step 1
Return to 02. When the stop reserve flag SRF is set to “1”, the step of FIG. 10 is executed at the next bar line timing.
The result of the determination in 307 is “YES”, and the flow proceeds to step 312.
In step 312, the step reserve flag SRF and the rhythm run flag RUN are reset, and the LED 29 is turned off. When the rhythm run flag RUN is reset, the first
Steps 302 and 313 in FIG. 0 are not executed together, so that the rhythm sound and the automatic performance sound are stopped. Next, when the stop / continue switch 30 is pressed again, steps 401 and 406 in FIG. 11 are sequentially executed, and the determination result of this step 406 becomes “YES”, so the routine proceeds to step 407. In step 407, the rhythm run flag RU
N is set to "1" again, and the LED 29 is turned on.
When the rhythm run flag RUN is set, thereafter, the rhythm sound and the automatic performance sound are generated again. Here, the address data ADR1 and ADR2, the read data RDD1 and RDD2, and the read timing data RDTIM1 and RDTIM2 are all
There is no change from the time when the continue switch 30 is pressed and the automatic performance is stopped. Therefore, when the rhythm run flag RUN is set to "1" again, the music is restarted from the position where it was stopped last time. As described above, when the stop / continue switch 30 is pressed during the automatic performance, the automatic performance is stopped, and when the stop / continue switch 30 is pressed again, the automatic performance starts again. Thereafter, each time the stop / continue switch 30 is pressed, this operation is repeated. If it is desired to perform an automatic performance from the beginning after stopping once, the start switch 28 may be pressed. The above is the details of the embodiment of the present invention. The eleventh
Instead of the stop / continue switch processing shown in the figure,
The processing of FIG. 14 may be performed. The processing shown in FIG.
The difference from the processing in FIG. 11 is that step 405 in FIG.
The point is step 410 in the figure. In step 410, step 411 is a step for determining whether or not the stop reserve flag SRF is "1". If the determination result in step 411 is "YES", step 41
Go to 2, reset the stop reserve flag SRF,
If “NO”, the process proceeds to step 413, where a stop reserve flag SRF is set. The meaning of the processing in step 410 is as follows. That is, the normal stop / continue switch 30 is pressed when the stop reserve flag SRF is "0", and in this case, the processing of step 410 and the processing of step 405 are not substantially changed. But,
If you change your mind before pressing the stop / continue switch 30 to stop the automatic performance (or writing data) before the timing of the next bar line, and want to cancel the "stop", in the process of Fig. 11, Although this cannot be done, in the process of FIG. 14, when the stop / conduit switch 30 is pressed again, steps 411 and 412 are executed, which causes the stop reserve flag SRF to return to “0” and “stop”. Can be canceled. [Advantages of the Invention] As described above, according to the present invention, when the operation switch is operated during the automatic performance, the automatic performance is stopped at the timing of the next bar line, and the automatic performance is stopped. After that, when the operation switch is operated again, the automatic performance is restarted. That is, according to the present invention, since the operation switch can be operated and paused at any timing between the bar lines, the phrase can be played when a part of the automatic performance device is played and ensemble is performed. Efficient when practicing separately. Further, in the case of performing with the automatic performance device, the present invention can easily stop / restart the automatic performance, so that the rest is stored in the memory corresponding to the time zone when the automatic performance device is not performing. Need not be stored, and as a result, memory capacity can be saved. Further, according to the present invention, when the operation switch is operated while writing the performance data, the data writing is stopped at the timing of the next bar line. That is, according to the present invention, since the writing can be ended by operating the operation switch at an arbitrary timing between the bar lines, the writing ending process becomes very simple.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention,
FIG. 2 is a front view showing the configuration of the operation panel 20 in the embodiment, FIG. 3 is a diagram showing a storage area of a performance data memory 63 in the embodiment, FIG. 5 to 13 show the CPU 72 according to the embodiment.
FIG. 14 is a flowchart showing another example of the process of FIG. 30 …… Stop / Continue switch (operation switch), 53 …… Automatic musical tone signal generation circuit, 62 …… Performance data memory, 72 …… CPU (central processing unit).

Claims (2)

(57) [Claims] 1. An automatic performance apparatus comprising a performance data memory for storing performance data, and an automatic performance means for reading the performance data in the performance data memory to automatically perform the automatic performance. An operation switch for instructing, an operation detection means for detecting an operation of the operation switch, an operation storage means for storing that the operation of the operation switch is performed, and an operation switch by the operation detection means during automatic performance. When the bar line timing is detected by the bar detection means during the automatic performance, the writing means for writing into the operation storage means the fact that the operation has been performed, the bar detection means for detecting the bar line timing during the automatic performance, Determining means for determining whether or not the operation switch stored in the operation storage means is operated, and the operation switch by the determining means. When it is determined that a touch operation has been performed, stop control means for stopping the automatic performance, and operation of the operation switch by the operation detection means while the automatic performance is stopped by the stop control means. An automatic performance device comprising a restart control means for restarting an automatic performance that has been stopped when detected. 2. Performance data memory for storing performance data, input means for inputting performance data, writing means for writing performance data input by said input means in said performance data memory, and said performance data. An automatic performance device comprising an automatic performance means for reading performance data in a memory and performing an automatic performance, an operation switch for instructing stop or start of writing of performance data, and an operation detection means for detecting an operation of the operation switch. And an operation storage means for storing that the operation switch is operated, and a writing for writing in the operation storage means that the operation switch was operated by the operation detection means during writing of performance data. Inputting means, measure detecting means for detecting bar line timing during writing of performance data, and the measure detecting means during writing of performance data. When the bar line timing is detected by, the determination means that determines whether or not the operation switch stored in the operation storage means is present, and when the determination means determines that the operation switch has been operated An automatic performance device comprising: stop control means for stopping the writing of the performance data.