JP3104705B2 - Rhythm musical tone control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [0001] [0001] The present invention relates to a plurality of sound source channels.
Channels and program rhythm patterns
Rhythm tone control device, especially rhythm pattern
Corresponding to the rhythm sound type designation information when programming
If there is a channel to which a rhythm sound type is assigned,
To the channel, otherwise to any channel
And assigns the sound type designation information to the rhythm sound type designation information.
By generating the corresponding rhythm sound signal,
The input rhythm sound is generated based on the number of channels and the rhythm pattern.
This makes it possible to generate a rhythm sound. [0002] 2. Description of the Related Art Conventionally, a plurality of rhythm sound source channels are provided.
The rhythm playing device that performs
Has multiple rhythm sound types (for example, bass drum, cymbal,
Snare drum ...) assigned to multiple rhythm sound source channels
The rhythm to play these rhythm sound source channels
According to the rhythm pattern for the type (eg March)
Rhythm performance is automatically performed by selective drive.
A known configuration is known (see, for example,
-191 publication). [0003] According to the above-mentioned prior art,
Then, once the rhythm type to be played is decided, for example
Liz to be generated in each of the eight rhythm sound source channels
The type of sound is fixed, and it is more than the number of channels
For example, the content is complicated and changes using 16 rhythm sounds
It was not possible to perform a rich rhythm performance. [0004] Moreover, such complicated rhythm performances are conventionally performed.
If you try to do this with a device, there is no other way to increase the number of channels.
And the configuration was inevitably complicated. It is an object of the present invention to provide a rhythm pattern
Input rhythm sound with a small number of channels
Enables generation of rhythm sounds based on raw and rhythm patterns
To provide a new rhythm musical tone control device. [0006] A rhythm music according to the present invention is provided.
The sound control device includes a sound source unit having a plurality of sound source channels.
And each sound source channel isBe assignedRhythm sound
It is possible to generate rhythm sound signals corresponding to the types
of(30 in FIG. 1)And more than the number of sound source channels
Multiple rhythm performances corresponding to multiple rhythm sound types
Playing operator(PDS in FIG. 1)And rhythm pattern information
Memorable storage means(20 in FIG. 1, FIG. 5 (A))And te
Means for generating a clock signal(22 in FIG. 1)And before
Each time one of the rhythm playing controls is operated
Rhythm sound type corresponding to the rhythm performance operator related to the operation
Rhythm sound type specifying information specifying the tempo and the tempo clock
Timing information for instructing sounding timing based on signals
Information in the storage means as the rhythm pattern information.
Writing means(130 to 152 in FIG. 10)And this write
Means for writing rhythm sound type designation information to the storage means.
Rhythm sound type designation information for writingLiz specified by
Sound type is assigned to any of the above-mentioned sound source channels
First determining means (15 in FIG. 10)
4)And this firstThe judgment result by the judgment means is
Assigning the plurality of sound source channels in response to
Write to the sound source channelRhythm sound type finger
And the first informationJudgment by judgment means
The plurality of sound source channels in response to a negative result.
Write to any of theRhythm sound type designation information
By assigning informationSuch sound sourceOn the channel
Rhythm sound type designation information pertaining to assignmentRhythm specified by
Sound typeAssignment for generating a rhythm sound signal corresponding to
means(156 to 162 in FIG. 10)When,This first assigner
Parallel to the rhythm performance based on the rhythm sound signal generation by the step
handThe tempo clock signal and the timing of the storage means
The sounding timing for each rhythm sound type based on the
Each time the rhythm sound typeSpecifyRhythm sound type designation
Information from the storage meansReading means for reading (20 in FIG. 13)
0 to 204, 232 to 242)When,Read by this reading means
Rhythm sound type specification for each rhythm sound type specification information
The rhythm sound type specified by the information is
Second determination to determine whether any of the
Means (206 in FIG. 13);This secondJudgment by judgment means
The plurality of sound source channels in response to a positive result.
Assignment of channelsTo the sound source channel pertaining to
The rhythm sound type designation information is allocated andSecond
In response to a negative determination result by the determination means,
Read to any of multiple sound source channelsPertain to
Assign by assigning rhythm sound type designation informationPerson in charge
Sound sourceRhythm sound type designation information related to assignment on the channel
InformationRhythm sound type specified byRhythm sound signal corresponding to
Second allocation means for producing(208 to 220 in FIG. 13)When
It is provided with. According to the rhythm musical tone control device of the present invention,
Operate the rhythm performance operator corresponding to the desired rhythm sound type
Then, the rhythm sound type designation information and the timing information are restored.
It is written in the storage means as the rhythm pattern information. This
Repeated input operations for multiple rhythm sound types
The corresponding rhythm pattern information can be stored,
A rhythm pattern can be programmed. Re
Operate the music performance controlsEvery time the first assignmentBehavior of the means
Rhythm sound signal corresponding to the input rhythm sound
Input rhythm sound
It can be easily confirmed.Also, 1 or
Multiple rhythm sound typesRhythm pattern information corresponding to
State rememberedNow, the second assignmentRhythm by operation of means
An automatic rhythm performance is performed based on the pattern information.
Therefore, the rhythm pattern can be programmed according to the automatic rhythm performance.
Program (rhythm sound input operation)
You. [0008] FIG. 1 shows an embodiment of the present invention.
This shows the configuration of such an electronic musical instrument. In this electronic musical instrument,
Generation of manual performance sounds based on keyboard operations, program mode
Rhythm pattern writing and manual reading during loading
Rhythm sound and auto rhythm sound, play mode
Generation of auto rhythm sounds, etc.
Therefore, it is controlled. 1 and FIG.
In FIG. 2, for example, a signal shaded like a TD in FIG.
The signal line must be a plurality of signal lines or a multi-bit signal
Represents the flow of In FIG. 1, a keyboard is provided on a data bus 10.
12, panel device 14, central processing unit (CPU) 16,
Program and data ROM (read only memo)
18) Data and working RAM (random
Access memory) 20, tempo timer 22, roll tie
24, truncation timer 26, tone generator for keyboard
(TG) 28, rhythm tone generator (T
G) 30 and the like are connected. The keyboard 12 has a large number of keys.
Key press information is detected for each key. The panel device 14 is used for controlling a musical tone or for controlling a performance.
Various controls and various display elements were provided.
Operation information is now detected for each operator.
ing. In the panel device 14, the present invention is implemented.
As controls related to, hand percussion
Pad operator PDS, rhythm selection operator RSS,
Ruler RLS and program mode selector
PMS, start / stop operator SPS, tempo
An adjustment operator TMN is provided. As the pad operator PDS, for example, a bus
32 kinds of Liz such as drum, snare drum, cymbal…
32 self-restoring pad switches corresponding to each
Switch is provided. As the rhythm selection operator RSS, for example,
N (arbitrary plural) types such as March, Waltz, Roomba ...
Each factory-set rhythm pattern
Corresponding to the first to Nth rhythm selection switches and the player
M-th resource for selecting the programmed rhythm pattern
And a rhythm selection switch. Also, each rhythm
A display element LD consisting of a light emitting diode is provided for each selection operator.
Rhythm selection to select the desired rhythm
When the operator is turned on, the corresponding display element LD
Lights up. The role designation operator RLS is, for example,
It consists of a return type switch, and is a desired pad operator (example
For example, turn on simultaneously with snare drum)
The rhythm sound corresponding to the pad operator.
(Continuous hit) pronunciation can be specified. The program mode designation operator PMS is an example.
For example, it consists of a self-resetting switch.
Program mode and play mode can be specified alternately
is there. A light emitting diode is provided near the operator PMS.
A display element PLD is provided.
The child PLD lights up when the program mode is specified.
It has become. The start / stop operator SPS is, for example,
The switch consists of a self-resetting switch.
Start and stop can be alternately instructed. The tempo adjusting operator TMN is, for example, a rotary type.
Knob to set the desired tempo
belongs to. Arranged in a row near the operator TMN
Tempo display element T composed of four light emitting diodes
An LD is provided, in program mode and play
Lights sequentially at a speed corresponding to the set tempo in mode
Thus, the tempo is displayed. CPU 16 is stored in ROM 18
It executes various processes according to the program.
Details of these processes will be described later with reference to FIGS.
Will be described. The ROM 18 stores programs for various processes.
In addition, the factory set rhythm pattern etc.
The data is also stored.
It will be described later with reference to FIG. The RAM 20 stores a resource programmed by the player.
Storage unit for storing data on the
In addition, various processing by the CPU 16
Storage unit used as a working register, etc.
Contains. FIG. 5 shows the contents stored in the RAM 20.
It will be described later with reference to FIG. The tempo timer 22 stores the tempo data TD
Generates a tempo clock signal TCL having a corresponding frequency
Each clock pulse of the signal TCL is shown in FIG.
3 used to start the tempo clock interrupt process
You. The roll timer 24 is provided with a roll clock signal.
Signal RCL, and each clock of this signal RCL
The pulse starts the roll timer interrupt processing of FIG.
Used for Clock generation cycle of roll timer 24
Is set to several tens [ms] as an example.
Can be arbitrarily set according to the player's operation or external signals
You may make it. The truncation timer 26
For generating a clock signal KCL.
Each clock pulse of L is divided by the truncation timer
Used to start the load process. Truncate tie
The clock generation cycle of the clock 26 is, for example, several tens [m].
s]. In this embodiment, three timers 22 and 2
4 and 26 are provided independently, but one timer
The required clock signal can be obtained by dividing the power appropriately.
it can. The keyboard TG 28 is detected from the keyboard 12.
Tone signal K corresponding to the key pressed based on the key press information
A TS is generated. The rhythm TG 30 is a pad operator PDS.
Operation and / or based on the selected rhythm pattern
A rhythm sound signal RTS is generated.
2 will be described later. The sound system 32 has a tone signal KTS
And to convert the rhythm sound signal RTS to sound
is there. FIG. 2 shows an example of the configuration of the rhythm TG 30.
In this example, eight rhythm sound source channels
By driving the channels in a time-sharing manner, up to eight
Zum sounds can be produced simultaneously. Register 4 connected to data bus 10
Of the numbers 0, 42, 44 and 46, 40 is the channel number.
(CH number) is stored, 42 is the rhythm sound type
A musical instrument code ICODE representing a class is stored;
44 is as shown with respect to the envelope waveform data EV.
Volume value corresponding to the attack level of the envelope
VLM is stored, 46 is the start of rhythm sound generation
Is stored.
You. Information to these registers 40, 42, 44, 46
The transfer is performed at the timing to be generated for each rhythm sound type.
Sometimes done. The write control circuit 48 includes an ICODE storage circuit
Out of the eight time-division channels included in 50,
Register to the channel corresponding to the CH number from
To assign the instrument code ICODE from the star 42
The writing circuit performs write control.
The stored instrument chords are stored cyclically, and
At the timing of the file. The write control circuit 52 includes a VLM storage circuit 54
Of the eight time division channels contained in the register
Register to channel corresponding to CH number from 40
Write control to assign volume value VLM from 44
The storage circuit 54 stores the assigned volume.
Cycle values are stored cyclically, and the
It is sent at the timing. The write control circuit 56 includes a KON storage circuit 58
Of the eight time division channels contained in the register
Register to channel corresponding to CH number from 40
Write control to assign key-on information KON from 46
The storage circuit 58 stores the assigned key.
ON information is stored cyclically, and the
It will be transmitted as a key-on pulse KONP at the timing
Swelling. The address generator 60 has eight channels.
Address information can be generated in a time-sharing manner, and key-on
When the pulse KONP is received, the channel assigned to KONP is assigned.
Address information is generated at the timing of The rhythm sound waveform memory 62 stores P as an example.
Is it an actual percussion instrument by CM (pulse code modulation) recording method?
Rhythm sound waveform (from the start of rise to the end of attenuation)
Rhythm) and memorized such a rhythmic sound waveform
The 32 kinds of Liz that can be specified by the pad operator PDS
The sound corresponding to each sound is stored. From the waveform memory 62, for each channel
A rhythm sound waveform corresponding to the assigned instrument code is added.
Read out according to the address information from the address generator 60.
You. For example, if a bass drum is assigned to channel 1
The bus at the timing of the first channel.
The ram sound waveform is read. The envelope generator 64 is provided for each channel.
For the rhythm sound corresponding to the assigned instrument code for each
The key-on pulse KON
P, which is generated in accordance with the envelope waveform data E
The attack level in the envelope indicated by V is
It is determined according to the volume value VLM from the road 54. Rhythm sound waveform data from the waveform memory 62
Envelope wave from WD and envelope generator 64
The shape data EV is supplied to the multiplier 66, and is output to each channel.
Is multiplied by Then, the product output MO of the multiplier 66 (data
Digital music signal), as already known
Analog format through an accumulator, D / A converter, etc.
Sound system after being converted to a sound signal RTS
32. According to the rhythm TG 30 described above, 8 channels
It is possible to simultaneously generate rhythm sound signals for channels.
In addition, each channel is lit by the instrument code ICODE.
By specifying the sound type, the waveform stored in the waveform memory 62
Various corresponding rhythm sound signals can be generated. FIG. 3 shows the contents stored in the ROM 18.
The ROM 18 stores a rhythm pattern as shown in FIG.
A storage unit used as a turn memory;
Storage unit used as truncated value memory
And used as volume value memory as shown in (C)
Memory section and other tone parameters and effect parameters
And a storage unit (not shown) such as a personal computer. In the rhythm pattern memory (A)
Means N types of rhythms (Rhythm 1 to Rhythm N)
Storage block RPM storing the corresponding rhythm pattern
EM (1) to RPMMEM (N) and their memory blocks
Track number storage that stores the number of tracks
Areas PTNNUM (1) to PTNNUM (N) are provided.
Have been. Memory block RPME corresponding to rhythm 1
M (1) is provided with 16 storage tracks.
And an instrument code storage area PICOD for each storage track.
E, role designation information storage area PRLFLG, and time
And a recording information storage area. Such a memory
Tracks and storage areas are arranged in other rhythms 2 to rhythm N
The same applies to
Each time it is required for it. For example, about rhythm 1
The number of tracks is 16 (PTNNUM (1) = 16)
There are 9 tracks (PTNNU) for rhythm 2
M (2) = 9), and for rhythm N, the number of tracks
Is 3 (PTNNUM (N) = 3). In each instrument code storage area PICODE,
An instrument code representing the rhythm sound type is stored, and each roll
There is a role specification in the specification information storage area PRLFLG.
Role designation information 1 or 0 indicating
Remembered. In this case, even if the same rhythm sound type
Different rhythm sound types for those with or without
Is treated as a kind. For example, just snare drum and snare
A separate memory track is provided with the Adulm Roll,
In these memory tracks, PICODE instrument code
Is the same for snare drums, but PRLFL
G roll specification information is 0 for a simple snare drum,
It is set to 1 for an adrum roll. Each timing information storage area has a tempo
Unta TPCTR count value 0 to 63
64) corresponding to 64 memory cells PTN
The memory section corresponding to the timing of
1 is the memory cell corresponding to the timing when sound generation is unnecessary
Are respectively stored in the. Tempo counter TPCT
R belongs to the RAM 20 as described later, and
The polock signal TCL is repeatedly counted every two measures.
It is. Therefore, the storage information of each timing information storage area
The report indicates a sound control pattern for two measures. FIG. 4 shows, as an example, a bass drum and a snare
One bar of time related to rum and snare drum roll
This is the data that is shown in the next bar.
The same timing data as shown
You. In FIG. 4, eight sounds can be generated within one beat
Timing (for example, TPCTR value 0-7)
, Bass drum, snare drum, snare drum roll
In each case, 1 for each soundable timing
(Required) or 0 (pronunciation unnecessary). 1 or 0
An arrow extending to the right from indicates that the same information will follow.
are doing. According to the timing data of FIG.
When the rum starts sounding at the beginning of the first beat and the beginning of the third beat,
The snare drum sounds at the beginning of the second beat and the beginning of the fourth beat
Begun. In addition, the snare drum roll
Instructs roll pronunciation for the period from the end of the second beat
During the period corresponding to this period, the roll timer shown in FIG.
A roll sound is generated by the interruption processing. For rhythms 1 to N,
Are set in the RAM 20.
The selected rhythm is stored in the program code register RCODE.
(For example, March)
You. Also, the track number register TR in the RAM 20
In N, a track number is set as described later.
You. Therefore, it is specified by using RCODE and TRN.
It is possible to read and specify a specific memory track
Can be. For example, FIG.
Assuming that RCODE = 1 and TRN = 10,
Storage track PICO
DE and PRLFLG information can be read.
If the TPCTR is used for the memory cell PTN, one shot
Reads out sound control information (1 or 0) for soundable timing
It is possible. Incidentally, the truncation value menu shown in FIG.
For the memory, 32 which can be specified with the pad operator PDS
Corresponding to each type of rhythm sound (instrument 1 to instrument 32)
The truncated value is stored. Each truncation value is
Consider the sounding period (especially decay time) of the corresponding rhythm sound type
In this example, the longer the pronunciation period, the larger
Value. In FIG. 3B, “musical instrument 1” is
Srum drum, "Musical instrument 2" is snare drum, "Musical instrument 32" is
This is an example of conga. In this example, the truncation value is
There is no distinction between normal sound and roll sound, but they are stored separately.
You may make it. In the volume value memory shown in FIG.
Is the same as the truncated value memory
Volume values VLM corresponding to the respective musical instruments 1 to 32
It is memorized. In this case, the normal sound and lo
Different volume values for the roll sound
The volume value is about half that of normal sound.
You. This is, for example, a snare drum as shown in FIG.
Same when the snare drum rolls sound simultaneously.
When played at one volume, the snare drum sound
It is masked by the roll sound,
Because it is not good. FIG. 5 shows the contents stored in the RAM 20.
The RAM 20 stores a rhythm pattern as shown in FIG.
A storage unit used as a turn program memory;
Used as memory for channel assignment as shown in (B)
And a working memory as shown in FIG.
Memory used as a keyboard, other panel controls, pronunciation
And a storage unit (not shown) relating to assignment and the like. (A) Rhythm pattern program memory
, The rhythm pattern corresponding to the rhythm code M
Memory block RPMMEM (M) for storing
The number of storage tracks used in the current storage block
Track number storage area PTNNUM (M) for
Have been killed. The storage block RPMMEM (M) contains 16
Storage tracks are provided, one for each storage track.
Instrument code storage area PICODE and role designation information
The storage area PRLFLG and the timing information storage area
Is provided. Data format in these storage areas
The mat is first stored in the rhythm pattern memory shown in FIG.
It is the same as described above. In the program mode, 32
When any of the pad controls PDS is operated,
In the storage area PICODE of track 1, the operated
Instrument code indicating the rhythm sound type corresponding to the pad operator
Is written. At this time, the role designation operator RLS is
If operated at the time, storage area PRLF of track 1
1 was written to LG, and the operator RLS was not operated
In this case, 0 is written to PRLFLG. Also,
The timing information storage area of the rack 1 stores the T
1 is written to the storage cell PTN corresponding to the value of PCTR.
You. Next, when another pad operator is operated,
Record track 2 in the same manner as described above for rack 1.
Storage area PICODE, PRLFLG and timing information
Instrument codes, role designation information and tags
Imming information is written. Next, the same pad operation as the first operation is performed.
Operating the child, as described above for track 1
Storage area PICODE, PRLFLG of track 1
And the timing information storage area.
Rule designation information and timing information are written. In this way, different from the already assigned
Each time a new pad controller is operated, a new track
Pattern is written in such a way that
For example, the rhythm pattern was completed with eight rhythm sounds
If there is, a rhythm pattern is stored in tracks 1 to 8
At the same time, the value of the storage area PTNNUM (M) finally becomes 8
Becomes In the program mode and the play mode
For example, as shown for track 8, RC
Storage areas PICODE and P using ODE and TRN
RLFLG can be specified, and TPCTR must be used.
Can specify the storage cell PTN. By the way, the channel allocation shown in FIG.
In the memory, each channel CH1 to CH8
Corresponding eight instrument code registers ICODE (1)
~ ICODE (8) and eight truncation counters T
CTR (1) to TCTR (8) and eight roll flags
RLFLG (1) to RLFLG (8) and 8 volumes
And VLM (1) to VLM (8) are provided.
Have been. Each instrument code register has a corresponding channel.
The instrument code is stored for the flannel. each
The truncation counter is
The data read from the truncation value memory of FIG.
Is used to store the truncated value.
The Kate value is obtained by the truncation timer interrupt processing in FIG.
It is subtracted (down counted) by one. Each roll flag
Indicates that role specification information is stored for the corresponding channel.
It is something that is done. Each volume value register corresponds
Volume value memo of FIG.
The volume value VLM read from the memory is stored.
It is. In the working memory shown in FIG.
Is provided with the following registers. (1) Rhythm code register RCODE ...
This corresponds to the operated rhythm selection operator RSS.
Rhythm code (1 to N or M) is stored
Things. (2) Pad code register PDCODE
… This is the resource corresponding to the operated pad operator PDS.
Musical instrument code indicating the type of rhythm sound (one of 1 to 32)
Is to be stored. (3) Tempo counter TPCTR ... this
Calculates the tempo clock signal TCL repeatedly every two measures
The count value is 0 to 63 within two measures.
And is reset to 0 at the timing when it becomes 64. (4) Program mode flag PRGFL
G: If this is 1, the program mode is set;
Each represents a ray mode. (5) Start flag START ... this
Is 1 for rhythm run, 0 for rhythm stop
These are shown respectively. (6) Role designation information register RLSW ...
This is 1 if the role designation operator RLS is operating.
Is set to 0 when not operating
is there. (7) Track number register TRN ...
This means that the track number (any of 1 to 16) is stored
Is what is done. (8) Assigned channel number register AC
H ... This corresponds to the channel to which the instrument code is to be assigned.
The corresponding channel number is stored. (9) Channel number register CHN ...
This means that the channel number (one of 1 to 8) is
It is something that is done. (10) Tempo count value register DTP
CTR: This is the value at the time of the last tempo clock interruption.
Tempo count value (1 minus the value of TPCTR
Value) is set. Here, various processes after FIG. 6 will be described.
Prior to this, we outlined the panel operations related to rhythm performance.
You. When you want to program a rhythm pattern
Is operated by operating the program mode designation operator PMS.
The gram mode is selected (the display element PLD is turned on). Soshi
Of the rhythm selection operator RSS
Operate the corresponding one to turn on the memory block RPMMEM.
(M) can be written. Further, if desired,
The tempo is set by the control knob TMN. this
Later, start with start / stop operator SPS
When commanded, display element TLD lights according to the set tempo
The pad operator PD according to the displayed tempo.
Operate one of S several times to get a specific rhythm sound type
Real-time timing information (for example, bass drum)
Enter in time. At this time, the input
Such a rhythm sound (manual rhythm sound) is generated. When such input is completed, another resource is input.
In the same way for rhythm sounds (for example, snare drum)
Perform input operation. At this time, the previously entered
When the auto rhythm sound is generated based on the
The manual rhythm sound being input is also generated. Similarly,
To perform the input operation for the required number of rhythm sound types.
Completes the rhythm pattern corresponding to rhythm code M
Once you have completed the entry,
A stop command is issued by the top operator SPS. On the other hand, based on a desired rhythm pattern,
If you want to play dynamic rhythms,
Select the play mode using the designated operator PMS (Display
The element PLD is turned off). And the rhythm selection operator RSS
The one corresponding to the desired rhythm (rhythm codes 1 to
N or M) is turned on. In addition, if desired
After setting the tempo with the tempo adjustment operator TMN,
Start command by start / stop operator SPS
I do. Then, the display element TLD turns on according to the set tempo.
Lights and plays according to the selected rhythm pattern.
A rhythm sound is generated. During generation of such an auto rhythm sound,
One that can perform a manual performance on the keyboard 12 with it as an accompaniment
On the other hand, by operating the pad operator PDS as desired,
It can also generate a near rhythm sound. FIG. 6 shows the flow of processing of the main routine.
This routine starts when the power is turned on, etc.
I do. First, in step 70, various registers are stored.
Initial setting. For example, START, PRGFLG,
0 is set in TPCTR and the like. Next, in step 72, key press detection and sound generation are performed.
Perform assignment processing. This means that key press information is detected from key press 12.
And assign it to the appropriate channel of the key press TG 28.
Generates a tone signal KTS corresponding to the key pressed.
This allows manual performance according to key press operations
Sound generation becomes possible. After step 72, step 7
Move to 4. Step 74 will be described later with reference to FIG.
Rhythm selection subroutine is executed as described above. And
Proceeding to step 76, the mode is
Execute the subroutine for selecting a node. After this, step 7
8 and start / stop as described below with respect to FIG.
Execute the subroutine of After step 78,
Move to step 80. At step 80, a tempo control process is performed.
U. That is, the setting tempo by the tempo adjusting operator TMN
Send tempo data TD corresponding to the
The tempo clock according to the tempo data TD.
The frequency of the clock signal TCL is set. And step
Move to 82. Step 82 will be described later with reference to FIG.
The subroutine of the pad operation is executed as follows. Soshi
Then, the process proceeds to step 84. In step 84, other panel operators
(For example, those relating to timbre, effects, etc.).
Thereafter, the flow returns to step 72 to repeat the above processing.
return. FIG. 7 shows a rhythm selection subroutine.
Things. Turn on one of the rhythm selection operators RSS
When an event occurs, at step 90
RCOD corresponding to the rhythm selection operator
Set to E. Then, the process proceeds to a step 92. At step 92, the operated rhythm is selected.
The display element LD corresponding to the operation element is turned on, and other display elements are turned on.
The child LD is turned off. Thereafter, the routine of FIG.
To Note that “RET” shown in FIG.
Mean. FIG. 8 shows a subroutine for mode selection.
Things. Turn on program mode designation operator PMS
When an event occurs, in step 100, the PRG
Invert the contents of FLG. That is, PRGFLG
If the value is 0, set it to 1; if it is 1, set it to 0.
You. Then, the process proceeds to step 102. In step 102, the value of PRGFLG is
1 (program mode). And this case
If the fixed result is affirmative (Y), the process proceeds to step 104. At step 104, the storage block RPM
Clear all the contents of EM (M) and save the storage area
PTNNUM (M) is also cleared. And step 1
06, and in the channel allocation memory of FIG.
Clear all the contents. Thereafter, in step 108,
The rhythm code M is set in RCODE. These processes
Is to enable the writing of new rhythm patterns
belongs to. After step 108, step 110
Move on to In step 110, the display element PLD is turned on.
Lights to indicate that it is in program mode. this
Thereafter, the process returns to the routine of FIG. If the determination result of step 102 is negative (N)
Is in play mode, and
To turn off the display element PLD, and then return to the routine of FIG.
To FIG. 9 shows a start / stop subroutine.
It indicates the The start / stop operator SPS is turned on.
When a vent occurs, in step 120, the STAR
Invert the contents of T. That is, the value of START is 0
If it is 1, it is set to 1, and if it is 1, it is set to 0. So
Then, the process proceeds to step 122. In step 122, the value of START is 1
(Start). Then, this determination result is
If it is constant (Y), the process proceeds to step 124, where TPCTR
Is set to 0. This is the rhythm when the rhythm starts
To allow the pattern to be read from the beginning of the first measure
It is. When the processing in step 124 is completed or when
When the judgment result of step 122 is negative (N)
(When it is a stop), the routine of FIG.
On. FIG. 10 shows a subroutine for pad operation.
It is something. One of the pad controls PDS
When an event occurs, in step 130, PRGFL
It is determined whether the value of G is 1 (program mode). This size
If the fixed result is negative (N), it is the play mode,
It returns to the routine of FIG. Step 130
If the determination result is affirmative (Y), the program mode
Then, the process proceeds to step 132. At step 132, the operated pad operation
The instrument code representing the rhythm sound type corresponding to
Set to CODE. Then, proceed to step 134.
You. In step 134, the role designation operator R
It is determined whether or not LS is on, and if the determination result is affirmative (Y),
If so, set RLSW to 1 in step 136, and negate
RLSW is set to 0 in step 138
To After step 136 or step 138,
Move to step 140. At step 140, TRN is set to 0.
I do. Then, the process proceeds to step 142, where the value of TRN is set to 1
Up. After step 142, go to step 144
Move on. In step 144, the rhythm of RCODE
Specified by the track number of code M and TRN
Instrument code of the storage area PICODE (M, TRN)
Rhythm code equal to PDCODE instrument code
Storage specified by M and TRN track numbers
Role designation information of region PRLFLG (M, TRN) and R
Whether the LSW role specification information is equal
The specified rhythm sound type is changed to M and TRN compatible tracks.
Is assigned). For example, the program mode
When the desired pad controller is operated for the first time after being specified
Since the value of PICODE (M, 1) is 0,
The determination result of step 144 is negative (N), and the
Move on to 146. At step 146, the value of TRN is set to the rhythm.
Storage area PTNNUM specified by code M
Judgment is greater than the value of (M) (number of tracks used so far)
I do. At the time of the first pad operation, PTTNNUM
The value of (M) is set to 0 in step 104 of FIG.
Since TRN = 1, the determination result of step 146 is
The result is affirmative (Y), and the routine proceeds to step 148. In step 148, the value of TRN can be used.
It is determined whether the maximum number of tracks is larger than 16. This judgment result
If the result is positive (Y), writing is not possible.
Return to routine. The result of determination at step 148 is negative (N).
, Since writing is possible, step 150
Move on to In this step 150, the PDCODE
Instrument code to PICODE (M, TRN), RLSW
Role designation information of PRLFLG (M, TRN), T
Track number of RN is set to PTNNUM (M)
Write. Then, the process proceeds to step 152. At step 152, the rhythm codes M, T
According to the track number of RN and the count value of TPCTR
Memory cells PTN (M, TRN, TPCT
Write 1 in R). Note that TPCTR is shown in FIG.
Not only during play mode, but also
The counting operation is performed even in the mode. By the way, the first pad operation as in the above-mentioned example is performed.
After paddle operation, the second pad operation
Then, the pad controller operated at this time
If the result is the same as the above, the determination result of step 144 is positive.
(Y), and the routine goes to Step 152. And step
In step 152, the same track as TRN = 1
The timing information is written in the same manner as described above. In this case, a pad operation different from the first one
Controls are operated or the same pad controls and
And the role specification operators are operated at the same time,
The determination result of step 144 becomes negative (N), and
Move to step 146. In step 146, TRN = 1, PTN
Since NUM (M) = 1, the judgment result is negative (N)
And returns to step 142. And step 14
The TRN is set to 2 in step 2, and the process proceeds to step 144. In step 144, the storage area of track 2 is
Area PICODE (M, 2) and PRLFLG (M, 2)
Are 0 (unassigned), so the judgment result is
The result is negative (N), and the routine proceeds to step 146. In step 146, TRN = 2, PTN
Since NUM (M) = 1, the determination result is positive (Y)
And the process proceeds to step 150 via step 148.
You. In step 150, a TRN different from the last time
Track 2 = Instrument chord and row
Is written and the PTNNUM (M) contains 2
Is written. Thereafter, in step 152, TRN =
Write timing information to track 2 as before
I will. As still another example, several pad operations are performed.
When PTNNUM (M) is 5, a new package
The routine of FIG. 10 is entered in response to the
When it comes to 6, TRN = 1, PTNNUM (M) = 5
Therefore, the determination result of step 146 is negative (N).
And returns to step 142. And step 14
Steps 2 and below are performed in the same manner as described above. In this way, even if the search is performed up to TRN = 5,
If there is no assigned track, T
After the RN becomes 6, the determination result of step 144 is negative.
(N). This means that track 6 has no instrument code
Not assigned (PICODE (M, 6) = 0
This is because that. Thereafter, at step 146, TRN =
6, PTNNUM (M) = 5, so the judgment result is positive.
Determinate (Y), and step 1 through step 148
Move to 50. Then, Step 150 and Step 15
In 2, the writing process for TRN = 6 is the same as described above.
It is performed. Further, as described above, TRN = 2, 3, 4,
In the process of sequentially examining in the order of 5, in this pad operation
If the rhythm sound type is already assigned to any track
If it is found, then from step 144
Move to step 152, where the TRN
The writing process of the timing information is performed for the member.
For example, tracks with TRN = 4 are assigned tracks
If it is found that, at that time step 144 to step
Move to 152, and write timing information regarding TRN = 4
Is performed. In this case, TRN = 5
I don't look at racks. In the processing of steps 132 to 152 described above,
According to this, every time the rhythm sound type is specified, the rhythm sound
It is determined whether the type has been assigned to any of the tracks,
If there is a track that has been assigned,
Type-related timing information is written while allocation
If there is no track already assigned, one of the unassigned tracks
The rhythm sound type is assigned and the rhythm sound type is
Relevant timing information is written. And this
By repeating such processing, the rhythm shown in FIG.
The desired rhythm pattern is stored in the pattern program memory.
Writing is enabled. After step 152, the process proceeds to step 154.
Move to the assigned channel as described below with respect to FIG.
(CH) Execute a detection subroutine. This subroutine
Chin finds channel to assign instrument code to
And the channel number corresponding to that channel is A
Set to CH. Then, the process proceeds to step 156. At step 156, the channel of ACH
PI is added to the register ICODE (ACH) corresponding to the number.
CODE (M, TRN)
The flag RLF corresponding to the channel number of ACH
Roll of PRLFLG (M, TRN) on LG (ACH)
Set the specified information. As a result, at step 154
The assigned rhythm sound type is assigned to the output channel.
It has been. 1 is set to RLFLG (ACH).
When the power is turned on, the roll timer interrupt processing of FIG.
Roll sound is automatically generated. Of step 156
After that, it moves to step 158. In step 158, the transaction shown in FIG.
Instrument code of ICODE (ACH) from Kate value memory
Read the truncation value corresponding to ACH channel
Set the counter TCTR (ACH) corresponding to the
To The truncated value of this TCTR (ACH) is
The truncated timer interrupt processing of FIG.
Is subtracted. Next, at step 160, FIG.
ICODE (ACH) instrument copy from volume value memory
And RLFLG (ACH) role specification information
The volume value VLM to be read is read and the channel of ACH is read.
Set in the register VLM (ACH) corresponding to the number
You. Thereafter, at step 162, the rhythm T
For the registers 40, 42, 44, 46 of G30, A
Channel number of CH, Musical instrument of ICODE (ACH)
Code, VLM (ACH) volume value, key-on information
The information KON is transmitted. For this reason, TG for rhythm
30 corresponds to the channel number of ACH
Indication of instrument code of ICODE (ACH) from channel
The rhythm sound signal corresponding to the rhythm sound type is VLM (AC
H) occurs at the attack level corresponding to the volume value of
It is. After step 162, the routine of FIG.
On. In the processing of steps 154 to 162 described above,
According to this, each time a rhythm sound type is specified,
Rhythms by assigning
A rhythm sound corresponding to the sound type is generated, and the
It is possible to perform manual rhythms when playing. Therefore, playing
While listening to the manual rhythm sound that they perform,
You can program the desired rhythm pattern. FIG. 11 is a diagram showing a subroutine for detecting an assigned channel.
The chin is shown. At step 170, the request related to the allocation request
The sound types are channel 1 (CH1) to channel 8 (C
H8) is determined. That is,
RCODE rhythm code and TRN track number
Storage area PICODE (RCOD
E, TRN) instrument code and channel number X (1 to
8) of the register ICODE (X) corresponding to
The instrument code matches and the RCODE rhythm code and
Storage area P specified by the track number of TRN and TRN
RLFLG (RCODE, TRN) role designation information and
Flag RLFLG (X) corresponding to channel number X
Channel X that matches the role designation information
Is determined. And the result of this determination is negative (N)
If so, the process proceeds to step 172, and if affirmative (Y),
If so, the process proceeds to step 174. In step 172, TCTR (1) to TCTR (1)
CTR (8) whose value is 0
), The channel number corresponding to the value 0
A (CH number) is put in ACH. Also, the one with the value 0
If there is no, the value of TCTR (1) to TCTR (8) is
CH channel corresponding to the smallest one (the one with the most attenuation)
Put the member in ACH. In step 174, the already allocated
The channel number X of the current channel is put in ACH. Stay
After step 172 or 174, the original routine (FIG. 10 or
Returns to FIG. 13). According to the above-described routine of FIG.
Assigned with all channels occupied
If there is a request to assign a new rhythm sound type other than
The rhythm sound types are TCTR (1) to TCTR (8).
Assigned to the channel corresponding to the smallest value
The rhythm sound type is the most attenuated
It will be pronounced instead of the rhythm sound type. The routine of FIG. 11 is replaced by the routine of FIG.
If used, RCODE rhythm code is M
Therefore, in step 170, PICODE (M, TR
N) Instrument code and PRLFLG (M, TRN)
The determination is made based on the rule designation information. In the routine of FIG.
Nothing was done when the play mode was determined.
Rhythm sounds can be generated based on pad operations during
One example is shown in FIG. At step 130 in FIG.
If it is determined, the process proceeds to step 180 in FIG. In step 180, the pad operator PDS
Indicates the rhythm sound type corresponding to the operated one of
Set the instrument code to PDCODE. And
Move to step 182. In step 182, RLSW is set to 0.
To Thus, in this example, the role specification information is forced.
Automatic roll sound is not performed because it is set to 0
However, as described above with reference to FIG.
Detect RLS operation and automatically generate roll sound
You may make it. Next, at step 184, the designated resource
Whether the rhythm sound type has been assigned to any of CH1 to CH8
judge. This determination is based on PICODE (RCODE, T
RN) and PRLFLG (RCODE, TRN)
11 except that PDCODE and RLSW are used.
This is performed in the same manner as in step 170. The determination result of step 184 is negative (N).
If so, the process proceeds to step 186, where the process shown in FIG.
Value in TCTR (1) to (8) in the same way as
Corresponds to the one with 0 or the smallest if there is no 0
Put CH number in ACH. The determination result of step 184 is positive (Y)
If so, proceed to step 188, where the
The channel number X of the channel being set is put in ACH. After step 186 or 188,
To 190, ICODE (ACH) and RLFLG
(ACH) contains PDCODE instrument code and R
Write the LSE role designation information (0). And
Move to step 192. In step 192, step 1 in FIG.
ICODE from the truncated value memory in the same way as 58
(ACH) is read and the TCT
Put into R (ACH). Then, the process proceeds to step 194.
You. In step 194, step 1 in FIG.
ICODE from volume value memory
(ACH) and RLFLG (ACH)
And read the value into VLM (ACH). And
Move to step 196. In step 196, step 1 in FIG.
ACH, ICODE (ACH) and V
Key-on information KON with contents of LM (ACH)
Channel to the TG 30 for
The rhythm sound signal corresponding to ICODE (ACH) is
It is generated at an attack level corresponding to LM (ACH). This
After that, the process returns to the routine of FIG. FIG. 13 shows the flow of the tempo clock interrupt processing.
This interrupt processing is performed by the tempo clock signal T
It is started for each clock pulse of CL. In step 200, the value of START is 1
(Rhythm running). This judgment result is negative
If (N), the rhythm is stopped, so the routine of FIG.
To return. The determination result of step 200 is positive (Y)
If so, the process proceeds to step 202, where 1 is set to TRN.
Cut. As described above, the processing after step 202 is
Program mode and play as long as START = 1
It is executed in any of the modes. Stay
After step 202, the process proceeds to step 204. In step 204, the rhythm of RCODE
Chord (selected rhythm) and TRN track number
Memory cell PT specified by and the count value of TPCTR
Whether the information of N (RCODE, TRN, TPCTR) is 1
(Which timing should sound?) This judgment result
If affirmative (Y), the process proceeds to step 206. In step 206, the process described with reference to FIG.
Execute the assigned channel detection subroutine as
You. That is, the rhythm sound type to be pronounced should be assigned
A channel is detected and the CH number of the channel is set to A.
Put in CH. Then, the process proceeds to step 208. At step 208, the rhythm of the RCODE
Storage area specified by code and TRN track number
Whether the information of the area PRLFLG (RCODE, TRN) is 1
(Whether there is a role specification) and the result of this determination is positive
If (Y), the process proceeds to step 210. In step 210, the value of TPCTR is
DTPC is the value obtained by subtracting 1 (previous tempo count value)
Put in TR. In this case, the subtracted value becomes "-1".
, "63" is entered in DTPCTR. Steps
After 210, the process proceeds to step 212. At step 212, the previous tempo count
Storage cells PTN (RCODE, TRN,
DTPCTR) information is 1 (at the timing of sound generation)
Judge). This determination result is negative (N).
Then, the timing data of the selected rhythm is shown in FIG.
This means that "0" has changed to "1". The determination result of step 212 is positive (Y)
Or the judgment result in step 208 is negative
(N) (normal sound without roll specification)
) Moves to step 214. This step 214
Then, ICODE (ACH) and RLFLG (ACH)
To PICODE (RCODE, TRN) instruments
Number and PRLFLG (RCODE, TRN) row
Set the file specification information. Step 212 via step 212
When it comes to the top 214, 1 is set to RLFLG (ACH).
Set. Next, at step 216, the process shown in FIG.
IC from the truncation value memory in the same way as
Read the truncated value corresponding to ODE (ACH)
Put in TCTR (ACH). Then, step 218
Move on to In step 218, step 1 in FIG.
ICODE from volume value memory
(ACH) and RLFLG (ACH)
And read the value into VLM (ACH). And
Move to step 220. In Step 220, Step 1 in FIG.
ACH, ICODE (ACH) and V
Key-on information KON with contents of LM (ACH)
Channel to the TG 30 for
The rhythm sound signal corresponding to ICODE (ACH) is
It is generated at an attack level corresponding to LM (ACH). The process proceeds from step 212 to step 220.
When the timing data comes, as shown in FIG.
Tempo clock signal when changing from "0" to "1"
Key-on pulse KO in synchronization with the clock pulse of TCL
NP is generated, and the roll is generated according to the pulse KONP.
The first sound in the sound is generated. And after this
Is independent of the tempo clock signal TCL.
The sequential sound in the roll sound is generated by the timer interrupt processing.
Generated. The generation period T of these sequential sounds is roll
Corresponding to the generation cycle of the clock signal RCL for
For example, it is several tens [ms]. When the processing of step 220 is completed or when
When the determination result of step 212 is affirmative (Y)
Moves to step 232. Determination result of step 212
Is positive (Y), the process proceeds to step 232.
Represents the timing data as shown in FIG.
Since "1" is continuous and roll sound is performed,
Do you need to perform steps 214-220
It is. By the way, if the result of the determination in step 204 is
When it is constant (N)
Moves to step 222. This step 2
In step 22, PRLFLG is performed in the same manner as in step 208.
It is determined whether the information of (RCODE, TRN) is 1. This size
If the fixed result is negative (N),
Step 2 because there is no need to perform
Move to 32. The determination result of step 222 is positive (Y)
If so, the process proceeds to step 224, and step 21 is executed.
The previous tempo count value is added to DTPCTR in the same way as 0.
Is set. Then, the process proceeds to step 226. In step 226, the same as step 212
PTN (RCODE, TRN, DTPCTR)
Is determined to be 1. This determination result is negative (N).
If "0" continues in the timing data
, And the process proceeds to step 232. The determination result of step 226 is positive (Y)
When the timing data is as shown in FIG.
This means that the value has changed from “1” to “0”, and step 2
Move to 28. In step 228, step 1 in FIG.
Search for the assigned channel for the roll sound in the same way as
And put the CH number in ACH. And
Move to step 230. At step 230, RLFLG (AC
Set H) to 0. As a result, the roll sound
As shown in FIG. 14, the timing data changes from “1” to “0”.
The clock of the tempo clock signal TCL when it changes to
It stops after the pulse. After step 230,
Go to step 232. At step 232, the value of TRN is incremented by one.
Step. Then, the process proceeds to step 234, where the value of TRN is
Corresponds to RCODE rhythm code (selected rhythm)
Number of tracks in storage area PTNNUM (RCODE)
It is determined whether it is greater. If this judgment result is negative (N)
If it returns to step 204, TRN> PTNNUM (RC
The above-described processing is repeated until ODE). example
For example, in the rhythm pattern memory of FIG.
If program 1 is selected, PTNNUM (1) = 16
Therefore, the above processing is performed 16 times. TRN> PTNNUM (RCODE)
Then, the determination result of step 234 becomes positive (Y).
Then, the process proceeds to step 236. In this step 236,
Drives tempo display element TLD based on TPCTR value
I do. That is, the value of TPCTR is 0, 8, 16,.
Display element TLD1 depending on which of
To TLD4 (from the leftmost one to the most
Lighting control is performed as shown in FIG.
As a result, it is possible to display the tempo according to the set tempo.
You. After step 236, the process moves to step 238. In step 238, the value of TPCTR is set to 1
Up. Then, the process proceeds to step 240, where the TPCT
Determines whether the value of R is 64 (whether it is the end of 2 bars) and the result of this determination
Is negative (N), the routine returns to the routine of FIG.
You. The determination result of step 240 is positive (Y)
, The TPCTR is set to 0 in step 242.
And then returns to the routine of FIG. Follow
Automatically using two bars of rhythm pattern repeatedly
Rhythm performance can be continued. FIG. 16 shows the roll timer interrupt processing.
Therefore, this interrupt processing is performed for each of the roll clock signals RCL.
It is started every clock pulse. At step 250, the value of START is 1
FIG. 6 if the result of this determination is negative (N).
Return to the routine. The determination result of step 250 is affirmative (Y)
If so, the process proceeds to step 252, where 1 is set to CHN.
Cut. As described above, the processing after step 252 is
Program mode and play as long as START = 1
It is executed in any of the modes. Stay
After step 252, the process moves to step 254. At step 254, the channel of CHN
The value of the flag RLFLG (CHN) corresponding to the number is 1
(Whether there is a role specification). This judgment result is positive
If it is the target (Y), the process proceeds to step 256. At step 256, C with role designation
HN channel number and CHN register ICO
Instrument code of DE (CHN) and register V corresponding to CHN
LM (CHN) volume value and key-on information KON
In the same manner as in step 162 of FIG.
0 from the channel corresponding to CHN to I
The rhythm sound signal corresponding to CODE (CHN) is converted to VLM (CH
N) Corresponding attack level (about half of normal sound level)
Generated by When the process of step 256 is completed,
When the judgment result of step 254 is negative (N)
(If no role is specified), go to step 258.
You. At step 258, the value of CHN is incremented by one.
Step. Then, the process proceeds to step 260, where the value of CHN is
It is determined whether the number is greater than eight. This judgment result is negative
If it is a target (N), the process returns to step 254, and CHN> 8
The above processing is repeated until the processing is completed. In this way each
Checks if a role is specified for each channel, and
If it does, a rhythm sound is generated. If CHN> 8, the decision at step 260 is made.
The result is positive (Y) and the routine of FIG.
On. According to the above-described roll timer interrupt processing,
Roll clock independent of tempo clock signal TCL
Since a roll sound is generated according to the signal RCL, the tempo
Change the roll sound generation time interval,
Can be set to any time between rolls regardless of tempo
Can be changed. FIG. 17 shows the truncation timer interrupt processing.
This interrupt processing is performed by the clock for truncation.
It is started for each clock pulse of the signal KCL. At step 270, the value of START is 1
If the result of this determination is negative (N),
Return to routine. The determination result of step 270 is positive (Y)
If so, the process moves to step 272, where 1 is set to CHN.
Cut. As described above, the processing after step 272 is
Program mode and play as long as START = 1
It is executed in any of the modes. Stay
After step 272, the process moves to step 274. At step 274, the channel of CHN
The value of the counter TCTR (CHN) corresponding to the number is 0
Is determined (end of sound generation). This judgment result is negative
If (N), the process moves to step 276, where TCTR (CH
The value obtained by subtracting 1 from the value of N) is stored in TCTR (CHN).
Cut. When the processing in step 276 is completed or when
When the determination result of step 274 is affirmative (Y)
If (sound generation has ended), the flow proceeds to step 278. At step 278, the value of CHN is incremented by one.
Step. Then, the process proceeds to step 280, where the value of CHN is
It is determined whether the number is greater than eight. This judgment result is negative
If it is a target (N), the process returns to step 274 and CHN> 8
The above processing is repeated until the processing is completed. In this way each
Check TCTR (CHN) = 0 for each channel.
If it is, the value of TCTR (CHN) is reduced by one. If CHN> 8, the decision at step 280 is made.
The result is positive (Y) and the routine of FIG.
On. The truncation method is limited to the method described above.
For example, (a) Decrease by 1 at every tempo clock interrupt
(However, the time until it reaches 0 depends on the tempo
), (B) Decrease by one each time there is a new pronunciation assignment,
(C) The longer the decay time, the smaller the truncation value
Set, add 1 each time an interrupt occurs, and
Assign a new rhythm sound type to the largest channel, etc.
There is a method. The present invention is limited to the above embodiment.
It is not something that can be implemented in various modified forms.
You. For example, the following changes are possible. (1) An example of control by software is shown.
However, it may be processed by dedicated hardware.
No. (2) The rhythm tone generator is P
An example of the CM waveform memory system was shown, but the sound source system
The present invention is not limited to this, and an FM sound source system or the like can be used as appropriate. Also,
Multi-channel parallel instead of multi-channel time division processing
Sound source configuration. (3) An example of an electronic musical instrument with a keyboard has been described.
However, a dedicated rhythm playing device may be used. (4) The channel allocation method is the last-come-first-served method.
Rhythm sound on each channel
Request for new rhythm sound assignment when assigned
First-come-first-served system which does not allocate this even if there is
May be. The method of truncation is as follows.
There are various things outside. (5) Musical instrument for rhythm tone generator
Although the example of sending chords has been described,
Parameter information (for example, for FM sound source control)
(Parameter information). [0190] As described above, according to the present invention,If
Program rhythm patterns using the rhythm
Rhythm sound type designation information or rhythm pattern
Regarding the rhythm sound type designation information based on the turn
The sound source key to which the corresponding rhythm sound type has already been assigned
If there is a channel, the sound source channel
Rhythm sound type designation information to some sound source channels
To generate a rhythm sound signal.
Input rhythm sound generation and rhythm pattern with a small number of channels
To produce rhythm sounds based on the
You. When there is an empty sound source channel,
Assigns rhythm sound type designation information to that channel,
When there are no available sound source channels, the rhythm sound signal
Rhythm sound type designation information is assigned to the channel with the highest attenuation.
Since it is assigned, whether or not there is an empty channel
Instead, a rhythm sound can be generated. Besides, the rhythm sounds
Read the volume control information for each type to control the volume of the rhythm sound signal.
Control, so the expression of the volume for each rhythm sound type
Simulate the pronunciation of acoustic instruments
There is also a clear effect.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a configuration of an electronic musical instrument according to an embodiment of the present invention. FIG. 2 is a block diagram showing a configuration of a rhythm tone generator 30. FIG. 3 is a diagram showing stored contents of a ROM 18; FIG. 4 is a diagram showing an example of timing data. FIG. 5 is a diagram showing stored contents of a RAM 20. FIG. 6 is a flowchart showing a main routine. FIG. 7 is a flowchart showing a rhythm selection subroutine. FIG. 8 is a flowchart showing a mode selection subroutine. FIG. 9 is a flowchart showing a start / stop subroutine. FIG. 10 is a flowchart illustrating a subroutine of a pad operation. FIG. 11 is a flowchart showing a subroutine for detecting an assigned channel. FIG. 12 is a flowchart showing pad sound generation processing in a play mode. FIG. 13 is a flowchart showing tempo clock interrupt processing. FIG. 14 is a signal waveform diagram for explaining a roll sounding operation. FIG. 15 is a diagram for explaining a tempo display operation. FIG. 16 is a flowchart illustrating a roll timer interrupt process. FIG. 17 is a flowchart showing a truncation timer interrupt process. [Description of Signs] 10 data bus, 14 panel device, 16 central processing unit, 18 program and data ROM, 20 data and working RAM, 22 tempo timer, 24
Roll timer, 26 ... Truncate timer, 30 ... Rhythm tone generator.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-62-67596 (JP, A) JP-A-55-41482 (JP, A) JP-A-52-25613 (JP, A) 16693 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) G10H 1/18 101 G10H 1/40

Claims (1)

(57) [Claims] Sound source means having a plurality of sound source channels,
Each sound source channel is capable of generating a rhythm sound signal corresponding to the assigned rhythm sound type, a plurality of rhythm performance operators respectively corresponding to a plurality of rhythm sound types greater than the number of the sound source channels, Storage means for storing rhythm pattern information; means for generating a tempo clock signal; and a rhythm sound type corresponding to the rhythm performance operator relating to the operation each time one of the plurality of rhythm performance operators is operated. Writing means for writing into the storage means the rhythm sound type designation information for designating the sound and timing information for designating the sound generation timing based on the tempo clock signal, as the rhythm pattern information; Every time the rhythm sound type specification information is written, the rhythm sound type specification information for writing is specified
The rhythm sound type to be used is any of the plurality of sound source channels.
A first determining means for determining whether the first determination means is assigned to the first determination means.
In response to the assignment of the plurality of sound source channels
The rhythm sound type designation information for writing is assigned to the sound source channel, and the result of the determination by the first determination means is negative.
Out of the plurality of sound source channels in response to
Either the first assignment for generating a rhythm tone signal corresponding to the rhythm tone kind designated by the rhythm tone kind designating information according to the allocation in the instrument channel in accordance with the assignment by assigning the rhythm tone kind designating information according to the writing of the Means and a resource based on the rhythm sound signal generation by the first assigning means.
Wherein said tempo clock signal and <br/> rhythm tone kind designating information for designating the rhythm tone kind each time it is sounding timing for each rhythm tone kinds on the basis of the timing information of the storage means in parallel to the rhythm performance and reading read hand <br/> stage from the storage unit, each rhythm tone kind every designated information is read by the read unit
The rhythm sound type designated by the rhythm sound type designation information is
Assigned to one of multiple sound source channels
A second judging means for judging and responding to a positive result of the judgment by the second judging means.
In response, the rhythm sound type designation information to be read is assigned to the assigned sound source channel of the plurality of sound source channels, and the judgment result by the second judgment means is negative.
Out of the plurality of sound source channels in response to
Either the second assignment for generating a rhythm tone signal corresponding to the rhythm tone kind designated by the rhythm tone kind designating information according to the allocation in the instrument channel in accordance with the assignment by assigning the rhythm tone kind designating information according to the reading of Rhythm musical tone control device comprising: 2. Sound source means having a plurality of sound source channels,
Each sound source channel is capable of generating a rhythm sound signal corresponding to the assigned rhythm sound type, a plurality of rhythm performance operators respectively corresponding to a plurality of rhythm sound types greater than the number of the sound source channels, Storage means for storing rhythm pattern information; means for generating a tempo clock signal; and a rhythm sound type corresponding to the rhythm performance operator relating to the operation each time one of the plurality of rhythm performance operators is operated. and writing the write means in the storage means as the rhythm pattern data rhythm tone kind designating information for designating a the timing information instructing the sound generation timing based on the tempo clock signal, and idle state in the plurality of instrument channels determination means for determining the attenuation state of the rhythm sound signals, each rhythm according to the writing in the writing means Type designation information
A first assignment means for generating a rhythm tone signal corresponding to the rhythm tone kind designated by the rhythm tone kind designating information according to the allocation in the instrument channel in accordance with the assignment by assigning to one of said plurality of instrument channels Before
To one of the instrument channels free state when the determination result in serial determination means indicates that there instrument channel of idle
Assign the rhythm tone kind designating information relating to write, rhythm sound determination result in the determination <br/> means according to the writing to the most advanced instrument channel attenuation of the rhythm tone signal when indicating no instrument channel of idle A type assigning unit for assigning the type designation information;
Wherein said tempo clock signal and <br/> rhythm tone kind designating information for designating the rhythm tone kind each time it is sounding timing for each rhythm tone kinds on the basis of the timing information of the storage means in parallel to the rhythm performance Reading means to read from storage means
And the rhythm sound type designation information read by the reading means.
A second allocating means for generating a rhythm sound signal corresponding to the rhythm sound type specified by the assigned rhythm sound type designation information in the assigned sound source channel by allocating to one of the plurality of sound source channels. , Said format
If the result of determination by the disconnection means indicates that there is an empty sound source channel, read out to any of the empty sound source channels.
Assign the rhythm tone kind designating information relating to the teeth, the most advanced instrument channel attenuation of the rhythm tone signal when the determination result in said determination means indicates no instrument channel of idle
A rhythm musical tone control device comprising: a unit for assigning rhythm tone type designation information for reading . 3. A sound source means having a plurality of sound source channels each capable of generating a rhythm sound signal and a plurality of storage units respectively corresponding to these sound source channels, wherein each sound source channel has a rhythm corresponding to the assigned rhythm sound type designation information. A sound signal is generated, and each storage unit is configured to store volume control information for controlling a volume of a rhythm sound signal generated in a corresponding sound source channel; A plurality of rhythm performance operators respectively corresponding to a plurality of rhythm sound types larger than the number of channels; a first storage means for storing rhythm pattern information; a means for generating a tempo clock signal; Each time one of the performance controls is operated, a rhythm sound type that specifies the rhythm sound type corresponding to the rhythm performance control related to the operation Writing means for writing class designation information and timing information indicating a sounding timing based on the tempo clock signal as the rhythm pattern information in the first storage means; and a plurality of writing means respectively corresponding to the plurality of rhythm sound types. A second storage means for storing the volume control information of each of the rhythm sound types, wherein the volume control information corresponding to each rhythm sound type is stored at each rhythm sound signal generation timing corresponding to the rhythm sound type designation information designating the rhythm sound type. And a rhythm sound type designation in the first storage means by the writing means.
Each time information is written, first determining means for determining whether the rhythm sound type specified by the rhythm sound type specifying information for writing is assigned to any of the plurality of sound source channels, and writing is performed by the writing means. The rhythm sound type designation information is assigned to any of the plurality of sound source channels in accordance with the result of the determination by the first determination means, and the rhythm sound type designation information is designated by the rhythm sound type designation information. split by storing the volume control information corresponding to the storage unit that corresponds to the instrument channel of the assigned reads from the second memory means
A first allocating means for generating a rhythm sound signal corresponding to a rhythm sound type designated by the rhythm sound type designation information at a sound volume corresponding to the volume control information stored in the storage unit in a sound source channel to be applied; Responding to a positive result of the determination by the first determining means, assigning the rhythm sound type designation information according to the determination to the sound source channel related to the allocation among the plurality of sound source channels, and Allocating rhythm sound type designation information to one of the plurality of sound source channels in response to a negative determination result by the determination means; and a rhythm sound signal by the first allocation means. Outbreak-based resources
Finger the rhythm tone kind each time it is sounding timing for each rhythm tone kinds on the basis of the parallel to rhythm playing the tempo clock signal and the timing information of the first storage unit
The rhythm tone kind designating information constant for from the first storage unit
Reading means for reading, and for each rhythm sound type designation information read out by the reading means, determining whether the rhythm sound type designated by the rhythm sound type designation information is assigned to any of the plurality of sound source channels. And assigning each rhythm sound type designation information read by the reading means to one of the plurality of sound source channels according to the result of the determination by the second determining means. split by storing the volume control information corresponding to the rhythm tone kind designated by the rhythm tone kind designating information from said second storage means in the storage unit corresponding to the instrument channel of the assigned reads
A rhythm sound signal corresponding to the rhythm tone kind to be specified of the rhythm tone kind designating information in an instrument channel in accordance with the count on the second allocation means for generating at the volume corresponding to the volume control information stored in the storage unit In response to the determination result of the second determination means being affirmative, rhythm sound type designation information related to the determination is assigned to the sound source channel related to the allocation among the plurality of sound source channels, and A rhythm sound type control device for assigning rhythm sound type designation information to one of the plurality of sound source channels in response to a negative result of the determination by the determination means. 4. Sound source means having a plurality of sound source channels,
Each sound source channel corresponds to the assigned rhythm sound type
Rhythm sound signal can be generated and multiple rhythm performances corresponding to multiple rhythm sound types.
First storage means for storing performance operators and rhythm pattern information
If, means for generating a tempo clock signal and any one of the plurality of rhythm performance operators being operated
Rhythm sound type corresponding to the rhythm performance operator related to the sound operation
Rhythm sound type specifying information for specifying the type and the tempo clock
Timing for instructing the sound generation timing based on the
And the first storage as the rhythm pattern information.
Writing means for writing to the means, and the writing means specifies a rhythm sound type in the first storage means.
Rhythm sound type designation information related to writing every time information is written
The rhythm sound type specified by
First determining means for determining whether any of them has been assigned
And for each rhythm sound type of the plurality of rhythm sound types.
Truncate control information corresponding to the length of the
Second memory means for storing the rhythm sound type designation information of the plurality of sound source channels.
Rhythm sound type finger for each sound source channel to which
The truncation control information corresponding to the
From the storage means and based on the truncation control information.
By measuring remaining sound time, the plurality of sound source channels
Channel and the decay of the rhythm sound signal.
The determination means for determining and the first determination means respond to a positive result.
In response to the assignment of the plurality of sound source channels
The resource related to the determination by the first determination means is assigned to the sound source channel.
And assigning the sound type designation information and the first determination
In response to a negative determination result at the step,
One of the plurality of sound source channels is determined according to the result of the determination in the step.
Rhythm sound type related to the judgment by the first judging means
The sound source channel related to the assignment by assigning the class designation information
Finger of the rhythm sound type designation information
Rhythm sound signal corresponding to the rhythm sound type
A first allocating means, the result of the determination by said determining means
Indicates that there is an empty sound source channel
Of the sound source channel in the empty state by the first determination means.
Allocate rhythm sound type designation information for the judgment, and
The judgment result at the step indicates that there is no sound source channel that is empty
When the rhythm sound signal is most attenuated, the sound source channel
Rhythm sound type designation related to the determination by the first determination means
An information allocating unit , and a resource based on a rhythm sound signal generated by the first allocating unit.
The tempo clock signal and the
Each rhythm sound type based on the timing information in the first storage means
Specify the rhythm sound type each time the sounding timing is reached for each class.
Rhythm sound type designation information from the first storage means
Reading means for reading and for each rhythm sound type designation information read by the reading means
The rhythm sound type designated by the rhythm sound type designation information is
Assigned to one of multiple sound source channels
A second judging means for judging and responding to a positive result of the judgment by the second judging means.
In response to the assignment of the plurality of sound source channels
The resource related to the determination by the second determination means is assigned to the sound source channel.
Rhythm sound type designation information and the second determination means
In response to a negative determination result at the step,
One of the plurality of sound source channels is determined according to the result of the determination in the step.
Rhythm sound type related to the determination by the second determining means
The sound source channel related to the assignment by assigning the class designation information
Finger of the rhythm sound type designation information
Rhythm sound signal corresponding to the rhythm sound type
A second allocating means, the result of the determination by said determining means
Indicates that there is an empty sound source channel
Of the sound source channel in an empty state by the second determination means.
Allocate rhythm sound type designation information for the judgment, and
The judgment result at the step indicates that there is no sound source channel that is empty
When the rhythm sound signal is most attenuated, the sound source channel
Rhythm sound type designation related to the determination by the second determination means
A rhythm musical tone control device provided with a device for assigning information.