JPS59197096A - Electronic musical instrument - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to an electronic musical instrument using a waveform memory reading method that generates musical tones by sequentially reading musical waveform information sequences stored in a waveform memory.

[Prior art]

Conventionally, in an electronic musical instrument using a waveform memory read method, when generating musical tones of a plurality of different tones, a plurality of waveform memories corresponding to each tone are provided, and musical waveform information strings of the corresponding tones are stored in these waveform memories. A specific waveform memory corresponding to the timbre selected and specified by the output signal of the timbre selection switch etc. is stored in advance, and a specific waveform memory corresponding to the specified timbre is made readable. The tone waveform information string stored in the waveform memory is read out by applying an address signal that sequentially changes at a speed corresponding to the waveform memory.

Memory elements such as ROMs are generally specified in terms of memory capacity in units of two, such as 4 bits and 16 bits. For this reason, when such a memory element is used as a waveform memory, there are restrictions on the size of the musical waveform information sequence to be stored, and conversely, there are unnecessary memory addresses where no information is stored, resulting in the memory element being The disadvantage was that it could not be used efficiently and became uneconomical. This means that different musical waveform information sequences are stored in a plurality of waveform memories, and a predetermined waveform memory is made readable in accordance with the range of the generated musical tone, and the musical waveform information stored in the waveform memory is readable. The same holds true for electronic musical instruments that are configured to generate different musical tones for each range by reading out rows.

[Object and structure of the invention]

The present invention has been made in view of the above-mentioned drawbacks, and its object is to provide an electronic musical instrument that can generate all musical tones while efficiently using memory elements.

To this end, the present invention stores musical waveform information sequences relating to a plurality of different tones (or tones) in a waveform memory in sequence, and corresponds to the tones (or tones) of the generated musical tones in response to the specified tones (or tones). ) is generated, and with the address value indicated by this start address information as an initial value, address information that sequentially changes from this initial value at a speed corresponding to the frequency of the generated musical tone is generated. The waveform memory is then read out.

[Embodiments of the invention]

FIG. 1 is a block diagram showing an embodiment of the present invention.
A sequential address information generation circuit 1 generates sequential address information qF that sequentially changes from "0" at a speed corresponding to the pitch of the pressed key on the keyboard section 2, and inputs this sequential address information qF to one addition input of an adder 3. supply to. The other addition input of the adder 3 receives start address information SAD from the start address information generation circuit 4 indicating the storage start address of the musical waveform information string of a specific tone. and,
The output information of this adder 3 is ADH (= SAD + (I
F) is given as address information input to the waveform memory 5.

Here, in the waveform memory 5, for example, as shown in the memory map of FIG. 2, musical waveform information strings relating to a plurality of different tones ① to timbre V are successively stored. On the other hand, the start address information generating circuit 4 is supplied with the output signals of the tone selection switches SW1 to SW5 that specify one of the tones ■ to tone ■. Storage start address of musical waveform information strings 1 to ■ rOJ, r240J, ... r960J
It is configured to selectively generate start address information SAD indicating . Such a start address information generation circuit 4 receives the output signals of the switches SW1 to SW5 and generates a predetermined storage start address rO', r240J.
.

...r960. Start address information SA shown in J'
Circuits generated by D'e arithmetic processing or each storage start address rOJ, r240J,...r96
This is realized by a memory or the like that stores 0J in advance, reads out the address according to the output signals of the switches SW1 to SW5, and outputs the read storage start address as start address information SAD.

Therefore, for example, when tone color selection switch SWZ is turned on to select and designate tone color n, start address information SAD of r240j is generated from start address information generation circuit 4. Then, in the adder 3, the sequential address information qF generated from the sequential address information generation circuit 1 and the start address information 5AD (= "240") are added, and the waveform memory 5 stores the address information ADH of r240+qFJ. is given. As a result, the tone ■
Each piece of information in the musical tone waveform information sequence is read out in sequence according to changes in address information qF. The musical sound waveform information string of the timbre (2) thus read out is converted into an analog musical tone signal in the sound generation circuit 6 and is generated as a post-musical tone. In the above embodiment, the waveform memory 5 stores a plurality of tone waveform information sequences corresponding to a plurality of tones (tones ■ to V). A plurality of tone waveform information sequences may be stored corresponding to a tone range (for example, a half-octave, one-octave, or every two octaves).

In this case, instead of the output signals of the switches SW1 to SW5, the start address information generating circuit 4 is supplied with a signal (for example, an octave code) indicating the range of the pressed key from the keyboard section 2, and the circuit 4 is supplied with a signal indicating the range of the pressed key. According to the signal, predetermined start address information SAD' is generated.

In this way, different musical tones can be generated for each range. In addition, musical waveform information strings are stored in the waveform memory 5 for each timbre and for each range, and the start address information generation circuit 4 is connected to the timbre selection switches SW1 to S.
It is also possible to generate the start address information SAD based on both the output signal of the WS and the signal indicating the range of the pressed key.

〔Effect of the invention〕

As explained above, the present invention sequentially and continuously stores musical waveform information sequences regarding a plurality of different tones (or tones) in a waveform memory, and specifies the tones (or tones) of generated musical tones.
In response to this, start address information indicating the storage start address of the musical sound waveform information string regarding the specified tone (or range) is generated, and the frequency of the generated musical tone is changed from this initial value using the address value indicated by this start address information as an initial value. The waveform memory is read out after all address information that changes sequentially at a corresponding speed is formed.

Therefore, the overall size of the waveform memory can be reduced, and musical tones corresponding to various tones (or ranges) can be generated.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention, and FIG. 2 is a memory map showing the stored contents of a waveform memory. DESCRIPTION OF SYMBOLS 1... Sequential address information generation circuit, 2... Keyboard section, 3... Adder, 4... Start address information generation circuit, 5... Waveform memory, 6... Intimation... - Sound generation circuit, SW1 to SW5...Tone selection switch. Patent applicant: Nichifu Musical Instruments Manufacturing Co., Ltd. Agent: Kazuko Yamakawa (and 1 other person)

Claims (3)

[Claims] (1) In an electronic musical instrument in which musical sound waveform information sequences relating to desired musical tones are stored in a waveform memory and musical tones are generated by reading this waveform memory, a plurality of musical sound waveform information sequences corresponding to a plurality of tones are stored. a waveform memory that sequentially and continuously stores timbres; timbre selection means for selectively specifying one of the plurality of timbres; A start address information generation means for generating all the start address information indicating the storage start address of the musical sound waveform information string, and a start address information generating means that generates all of the start address information indicating the storage start address of the musical sound waveform information string, and at a speed corresponding to the frequency of the musical tone to be generated from this initial value, with the address value indicated by the start address information as an initial value. An electronic musical instrument comprising address information generating means for generating sequentially changing address information and supplying the generated address information to the waveform memory. (2) The address information generating means includes a sequential address information generating means for generating sequential address information that sequentially specifies each piece of information in the musical sound waveform information sequence at a speed corresponding to the frequency of the musical instrument to be sounded; and the sequential address information. 2. The electronic musical instrument according to claim 1, further comprising an adding means for adding the start address information and the start address information and generating the added value as the address information. (3) Musical sound waveform information strings related to desired musical tones In an electronic musical instrument that stores musical sound waveform information sequences in a full waveform memory and generates musical tones by reading out this waveform memory, a plurality of musical waveform information strings corresponding to a plurality of musical ranges are stored. a waveform memory that sequentially and continuously stores the following information, and a start address information generator that generates start address information corresponding to a range of musical tones to be generated and indicating a storage start address of a string of musical waveform information corresponding to the range in the waveform memory. and address information generating means that uses the address value indicated by the start address information as an initial value, and generates address information that sequentially changes from this initial value at a speed corresponding to the frequency of the musical tone to be generated, and supplies the generated address information to the waveform memory. An electronic musical instrument equipped with