JPH03213899A - Electronic keyboard musical instrument - Google Patents

Abstract

PURPOSE:To enable performance over a wide key area while adding automatic accompaniment by detecting chords from the input of pitch information from outside, e.g. a MIDI instrument and carrying out the automatic accompaniment. CONSTITUTION:A chord detecting means inputs the pitch information from outside and detects the chords from the pitch information and an automatic accompaniment pattern generating means generates a pattern for the automatic accompaniment. A musical sound generating means 20 generates a musical sound for the automatic accompaniment according to the chords detected by the chord detecting means and the pattern of the automatic accompaniment generated by the automatic accompaniment pattern generating means. A player, on the other hand, can play by using all the keys of the keyboard to generate musical sounds corresponding to the keys. Consequently, the automatic accompaniment can be added without decreasing the number of the keys of the keyboard which can be used for normal performance without the automatic accompaniment.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention automatically detects chords by manually inputting pitch information from the outside without reducing the number of keys on a keyboard that can be used in normal performance. This invention relates to an electronic keyboard instrument that can add accompaniment.

[Prior Art] Conventionally, electronic keyboard instruments equipped with a so-called automatic accompaniment function are known. This is done by setting a predetermined range of the keyboard as the range of the accompaniment keyboard in advance, and when adding automatic accompaniment, the press of one or more keys on this accompaniment keyboard is detected, and the state of this key press is detected. This system detects chords from the music and generates automatic accompaniment sounds consisting of bass notes, chord notes, etc. based on a specified rhythm (automatic accompaniment pattern).

The portion of the keyboard other than the accompaniment range can be used as a melody keyboard. When a key is pressed within this melody keyboard range, a musical tone (keyboard sound) corresponding to the pressed key is generated. In this way, the performer can add automatic accompaniment by pressing several keys on the accompaniment keyboard, and the melody keyboard can generate melody sounds corresponding to the pressed keys. can play.

[Problems to be Solved by the Invention] Generally, a key range of one octave or more is allocated for automatic accompaniment, and key presses are detected within that range. Therefore, when performing while adding automatic accompaniment, the key range other than automatic accompaniment (key range for melody) becomes narrow, resulting in the inconvenience that a satisfactory performance cannot be performed.

In view of the above-mentioned problems with the conventional type, the present invention provides an electronic keyboard instrument that can add automatic accompaniment without reducing the number of keys on the keyboard that can be used in normal performances without adding automatic accompaniment. The purpose is to

[Means for Solving the Problems] To achieve this object, the present invention provides an electronic keyboard instrument that has a keyboard with a plurality of keys and can simultaneously generate a plurality of musical tones by pressing each key. a chord detecting means for inputting pitch information from the outside and detecting a chord based on the pitch information; an automatic accompaniment pattern generating means for generating an automatic accompaniment pattern; and a chord detected by the chord detecting means. and musical tone generating means for generating automatic accompaniment musical tones based on the automatic accompaniment pattern generated by the automatic accompaniment pattern generating means.

[Function] According to such a configuration, the chord detecting means inputs pitch information from the outside and detects a chord based on this pitch information. The automatic accompaniment pattern generating means generates a pattern for automatic accompaniment. Then, based on the chord detected by the chord detecting means and the automatic accompaniment pattern generated by the automatic accompaniment pattern generating means, musical tones of automatic accompaniment are generated by the musical tone generating means. On the other hand, the player can play using all the keys on the keyboard, and corresponding musical tones are generated in response to the pressed keys.

[Example] Hereinafter, the present invention will be explained in detail using the drawings.

FIG. 1 is a block diagram of an electronic keyboard instrument according to an embodiment of the present invention. In this figure, 11 is a central processing unit (CP) for controlling the entire operation of the electronic keyboard instrument.
U), 12 is a tempo clock generator for issuing timer interrupts to the CPU II, and 13 is a random access memory (R) used for work registers or flags.
AM), 14 is a read-only memory (ROM) in which programs executed by the CPU II are stored, 15
is a pattern memory in which automatic accompaniment patterns are stored, 16
17 is a keyboard, 17 is a mode switch, 18 is a switch other than the mode switch, 19 is a MIDI interface that accepts MID1 input, 20 is a musical tone forming means (sound source), and 21 is a sound system. Each of these blocks is connected to a bidirectional path line 22.

Next, the registers or flags used in the electronic keyboard instrument of this embodiment will be explained.

(1) MODE: Mode register. “0° is normal mode, “1” is accompaniment key automatic performance mode (key ABC (
"2" represents MIDI automatic performance mode (MIDI/ABC mode), respectively.

(2) KCD: Key code register that stores the key code. The key code register provided for each sound generation channel and whose sound generation channel is the i channel is represented by KCD i.

(3) ROOT: Root note register for storing the root note of the detected chord.

(4) TYPE: Chord type register for storing the chord type of the detected chord.

(5) KON: “1” when there is a key-on of a keyboard key.
A key-on flag that is set to ``0'' and reset to 0' when the key is turned off.

Next, the operation of the electronic keyboard instrument according to this embodiment will be explained with reference to the flowchart of FIG. When processing starts in this electronic keyboard instrument, initialization is performed in step Sll, key press processing is performed in step S12, MIDI processing is performed in step S13, and step S
After performing mode switch processing in Step 14 and performing other processing in Step 815, the process returns to Step S12. Repeat the above loop processing.

The mode switch processing routine of step S14 in FIG. 2 will be explained with reference to FIG.

In the mode switch processing routine, step S2
1, it is determined whether the key ABC switch among the mode switches 17 is turned on. key AB in step S21.
When the C switch is turned on, step S is performed to set the accompaniment key automatic performance mode (key ABC mode) in which automatic performance is performed based on the keys pressed in the accompaniment key range by the performer.
At step 22, "1" is stored in the mode register MODE, and the process proceeds to step 523. If there is no key ABC switch on event in step S21, directly step 323
Proceed to.

In step S23, the mode switch 17 is set to MIDI.
- Determine whether the ABC switch is turned on. M
If the IDI/ABC switch is turned on, "2" is stored in the mode register MODE in step S24 to set the MIDI automatic performance mode (MIDI-ABC mode) in which automatic performance is performed based on external input. After that, the process advances to step S25. MID at step 823
If the I.ABC switch is not on, the process directly advances to step S25.

In step S25, it is determined whether the normal switch among the mode switches 17 is turned on. If the normal switch is on, in order to enter the normal mode in which automatic accompaniment is not performed and musical tones (keyboard sounds) corresponding to the player's key presses are generated, "01" is stored in the mode register MODE in step S26. , return.If there is no normal switch on event in step S25, return directly.

Through the above processing, the performance mode corresponding to the operation of the mode switch is set in the mode register MODE.

Referring to FIG. 4, in the key press process of step S12 of FIG. 2, first, in step S31, the mode register MO is
It is determined whether DE is "1" or not. 1", it is the accompaniment key automatic performance mode, so the process branches to step S41. In step S31, the mode register MODE
If not "1", it is determined in step S32 whether or not there is a key-on event. If there is a key-on event, the process proceeds to step 53B; otherwise, the process branches to step S36.

In step 533, channel assignment processing is performed to generate musical tones corresponding to the turned-on keyboard keys. The assigned channel number is assumed to be i.

Next, in step S34, "1"' is stored in the i-channel key-on flag KONi, and the key code of the key with the on-event is stored in the key code register KCDi. Then, in step S35, note-on and key code KCDi are sent to the sound source 20 to generate a musical tone, and the process proceeds to step S36.

In step S36, it is determined whether or not there is a key-off event. If there is no key-off event, the process directly returns; if there is a key-off event, the process advances to step S37. In step 83.7, a search is made for a channel that is being sounded with a key code that matches the key code of the key where the key-off event occurred. Then, in step S38, it is determined whether or not there is a corresponding channel. If there is a channel with the corresponding channel number i, the process advances to step S39; if there is not, the process returns directly. In step S39, the key-on flag KONi of the i-channel is cleared to zero, and in step S40, a note-off is sent to the i-channel of the sound source 20 to mute the sound, and the process returns.

If the mode register MODE is "1" in step S31, it is determined in step S41 whether or not there is a key-on event. If there is a key-on event, the process advances to step S42; if there is no key-on event, the process returns directly.

In step S42, the key range of the key where the on event occurred is determined.

If the key range is a normal range, that is, a melody keyboard range, it is necessary to generate a musical tone corresponding to the pressed key, so the process branches to step S33 and a corresponding keyboard tone is generated.

If the keyboard range of the key where the key-on event occurred in step S42 is the ABC range, that is, the accompaniment keyboard range,
In step S43, a chord is detected from the combination of keys pressed, the root note is stored in the register ROOT, and the chord type is stored in the register TYP.
Store each in E and return.

As described above, in the normal mode or MIDI automatic performance mode, musical tones (keyboard sounds) corresponding to pressed keys are generated in all keyboard ranges. On the other hand, in the accompaniment key automatic performance mode, automatic accompaniment or sound corresponding to the pressed key is performed in accordance with the key range of the pressed key.

Referring to FIG. 5, MIDI in step 313 of FIG.
In the process, first in step S51 it is determined whether the mode register MODE is "2". When the mode register MODE is "2", it is the MIDI automatic performance mode, so in step S52, pitch information is input by external MIDI input, a chord is detected from the key code combination, and the root note is registered. The types of chords are stored in ROOT and the register TYPE. after that,
Proceed to step 85B. If the mode register MODE is not "2" in step S51, the mode is normal mode or accompaniment key automatic performance mode, and the process branches to step S53. After performing other MIDI processing in step 553, the process returns.

Through the MIDI processing described above, a chord is detected from an external input in the MIDI automatic performance mode, and its root note and chord type are stored in a predetermined register.

Referring to FIG. 6, the tempo clock interrupt processing routine in the electronic keyboard instrument of this embodiment will be explained.

The tempo clock interrupt processing routine is a process executed by the CPU 11 based on an interrupt signal generated from the tempo clock generator 12 at predetermined time intervals.

In the tempo clock interrupt processing, first step S
61, it is determined whether the mode register MODE is 01 or not. When the mode MODE is "0", it is the normal mode, so the process returns directly. mode MO
If DE is other than "0", it is the accompaniment key automatic performance mode or the MIDI automatic performance mode, so step S6
In step 2, a pattern corresponding to the rhythm type is selected and data to be generated is read out based on the tempo clock value.

Next, in step 563, it is determined whether there is any control data to be generated. If there is data to be pronounced, step S
The process advances to step S64, and if there is none, the process branches to step S67. In step S64, the read control data is modified based on the chord type TYPE, and the root note ROOT is added to generate note data to be generated. Then, in step S65, octave information of the range to be sounded is added, and in step S66, the data processed in this way is sent to the sound source 2.
0 to generate a musical tone. And step S
Step 67 increments the tempo clock and returns.

Through the tempo clock interrupt processing as described above, musical tones for automatic performance in the automatic accompaniment key performance mode or the automatic MIDI performance mode are generated.

Note that external input of pitch information may be performed using other MIDs, for example.
Any device that can generate pitch information, such as an I keyboard or a sequencer, may be used. If this invention is applied to a teaching electronic musical instrument system in which multiple electronic musical instruments as slave units are connected to one electronic musical instrument as a base unit, pitch information for automatic accompaniment can be transmitted from the base unit. It is possible to send the music to each slave unit, and perform a key-pressing performance on each slave unit while adding an automatic performance.

In the above-described embodiment, the pitch information is manually transmitted using the MID1 system, but the present invention is not limited to this, and other transmission systems may also be used. Normal, key ABC, or MIDI-ABC modes are switched using a mode switch, but using MIDI signals etc.
It may also be possible to switch from the outside. Further, in the above embodiment, an example of an auto bass chord that adds a bass tone and a chord tone is shown, but the present invention is not limited to this, and can be applied to any type of automatic accompaniment. Also,
It can also be controlled using hardware instead of software.

[Effects of the Invention] As explained above, according to the present invention, chords are detected and automatic accompaniment is performed by inputting pitch information from an external device such as MIDI. To perform in a wide keyboard range while adding automatic accompaniment without reducing the number of keys on a keyboard that can generate musical tones.

[Brief explanation of drawings]

FIG. 1 is a block configuration diagram of an electronic keyboard instrument according to an embodiment of the present invention, FIG. 2 is a flowchart for explaining the main routine operation of the electronic keyboard instrument of this embodiment, and FIG. FIG. 4 is a flowchart for explaining the operation of the mode switch processing routine of the electronic keyboard instrument of this embodiment. FIG. 4 is a flowchart for explaining the operation of the key press processing routine of the electronic keyboard instrument of this embodiment. is a flowchart for explaining the operation of the MIDI processing routine of the electronic keyboard instrument of this embodiment, and FIG. 6 is a flowchart for explaining the operation of the tempo clock interrupt processing routine of the electronic keyboard instrument of this embodiment. . 11: CPU, 12: Tempo clock generator, 13: R
APvll 14: ROM, 15: Pattern memory, 1
6: keyboard, 17: mode switch, 18: other switches, 19: MIDI interface, 20: musical tone forming means, 21: sound system.

Claims (1)

[Claims] (1) In an electronic keyboard instrument that has a keyboard with multiple keys and can generate multiple tones at the same time by pressing each key, pitch information from an external source is input and the pitch information is chord detection means for detecting a chord based on the chord detection means; automatic accompaniment pattern generation means for generating an automatic accompaniment pattern based on the chord detected by the chord detection means and the automatic accompaniment pattern generated by the automatic accompaniment pattern generation means; 1. An electronic keyboard instrument comprising: a musical tone generating means for generating an automatic accompaniment musical tone.