JPS62187876A - Automatic composer - 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 automatic music composition machine that can automatically create music.

[Prior Art] Conventionally, when a composer composes a piece of music, he or she does not know whether the piece is good or bad.
It depends on the composer's ability to compose music, which can be acquired through specialized education and training during a period of study at a music college or the like. In response, an automatic composing machine (Japanese Patent Application No. 56-125603, Japanese Patent Publication No. 60-40027) has been proposed that allows even an outsider to compose music. This 1゛1
The motion music machine stores multiple types of pitch data in advance,
These are read out in random order to compose a song.

[Problems with the prior art] However, since such h-commercial devices only store pitch data, they cannot determine the relationship between two pitches before and after, which is a major element in forming a melody. The data represented does not exist in memory.To explain this using an example of 0, we use the pentatonic scale, which is often used in phrases.
Both scales, which are often used in Japanese nursery rhymes, include ``do, shi, mi, n, te,'' and their characteristics differ from the relationship between the two pitches, which are around 5. Therefore >7
Automatically composing music using only high data ran the risk of creating a piece of music that did not fit the intended style.

[Purpose of the invention] This invention was made in view of the above-mentioned circumstances, and its purpose is to provide an automatic composing machine that can automatically compose a piece of music that matches the intended musical style. It is in.

[Summary of the Invention] In order to achieve the above-mentioned purpose, this invention stores the frequency of changing from a certain jf high to a certain 1' high, and calculates the difference between this frequency and a random number (then, The key point is that the key pitch to be played next is calculated from the obtained pitch.

[Structure of Example] Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

Fig. 1 shows the overall circuit of an automatic music composer. In the figure, 1 is a storage device. As shown in Fig.
C4-C5) Frequency data indicating the frequency of change to a certain rf height (toc4-C5) is stored, and this frequency data is input to the FA calculation circuit 3. The random number generator 2 also provides random number data to the arithmetic circuit 3.
Random number data with high chance is added to the inevitable frequency data, and the pitch to be changed next is calculated from the pitch of the thorn, and is set in the phrase storage device 4. The music information consisting of a series of pitch data set in the phrase storage device 4 is sent to the musical tone generator 2i5 to generate and emit musical tones according to the music, and is also given to the CRT 6 to be displayed as a musical score. , and is further sent to a musical score printer 7 to be printed out as a musical score.

The variable weight resistor 8 controls the weighting of the frequency data and the random number data.A constant voltage V is applied to one end of the variable weight resistor 8, and the other end is grounded. WI! The divided voltage potential from the h element is transferred to the A/D converter 9.
A-DC (Analog-Digital) is converted into the arithmetic circuit 3! The calculation is performed according to the change. The greater the weighting, the greater the frequency data, and the greater the likelihood of inevitability in pitch changes; the lower the weighting, the smaller the random number data, the greater the chance of pitch changes.

The pitch data computed by the arithmetic circuit 3 is set in the address controller 711O and used as read address data of the storage device 1, and frequency data for determining the next pitch data is read out. . In addition, storage device 1
In addition to what is shown in FIG. 2 above, a plurality of frequency data with different musical styles are also stored, and each frequency data is selected by the musical style selection device 2111, and the leading address of each storage area is set accordingly. is set in the address control device 10, and the frequency data of the storage area is read out. FIG. 2 shows the frequency data of phrases.

The 1i-th determining device 12 is a device that determines the first 1-g in automatic composition, and usually mf! Consisting of i.

The arithmetic circuit 3 has the functions necessary for automatic composition, such as engineering, NOlMAX,
MEN, RAM, and x registers are provided.

[Operation of the embodiment] Next, the operation of this embodiment will be described.

Now, the weighting of the variable weight resistance 'jjia' is set to rOJ, the music style selection device 11 selects the blues style shown in FIG. 2, and the 1st i'9. Assume that the pitch of C4 is specified as the first note ■ by the determining device 12 of . Then, arithmetic circuit 3
is the I register and the N register at steps St and S2 shown in FIG.
The O register and the MAX register are cleared, and in step S3, the first frequency data M (1
)=3 in the MEN register, and at this time, the random number generator 2 generates R(1)=117 as shown in FIG.
Suppose that random number data is obtained, this random number data R(
1) Set =117 in the RAM register.

Next, in step S4, the arithmetic circuit 3 multiplies the frequency data of "3" in the MEN register by the weighting data rQJ to make it "0", and adds the random number data of the RAM register rl17J to this to obtain the calculated data X of rl17J. , in step S5, it is determined whether or not it is greater than rQJ of the MAX register. Now, X is "l17" and the MAX register is "
O'', and since X is larger, the arithmetic circuit 3 performs step S.
Proceeding to step 6, the operation result data X of rl17J is set in the MAX register, and the value of the I register of rlJ at this time is set in the NO register.

As a result, the largest one among the calculation result data X up to that point is selected, and the corresponding pitch number is set in the NO register.

Then, the arithmetic circuit 3 increments the value of the I register by 1 in step S7, and selects the one whose arithmetic result data X in steps 33 to S7 has the maximum value until the value of the register becomes "lO". Go (step S8).

In these 10 calculations, the frequency data is "3, 3.9.2, l...
...2'' is used, and as the random number data, for example, the third
rl17.45.226...9 as shown in the figure
2" is obtained, and the weighting data is "O", X becomes the maximum random number data r246J, the corresponding pitch number is "6", and the corresponding pitch number is "6".
F4" is the pitch to be played next.

Then, in the same way, the pitch to be played next is determined from this "F4", and thereafter performance patterns are sequentially formed based on random number data in the same manner.

In this way, when the weighting data is set to "0", the pitch to be played next is determined based only on the random number data without considering the frequency data.

The performance pattern is highly coincidental compared to the blues style.

On the other hand, weighting reduces data to near infinity, e.g. rl
oooJ, and select the song style selection device 11 as in the above case.
Assume that you select a blues style, specify the pitch of C4 as the first ff, and obtain random number data as shown in FIG. Then, the arithmetic circuit 3 starts the automatic composition process shown in FIG. 4, but this time the weighting data is rl.
ooo'', the calculation result data X is [3117,
3045, 9226, 2215,--1034, 20
92J, random number data rl17.45.226.2
15,...34,92J is hardly taken into consideration, and In degree day') r3.3.9.2,...1.
2". As a result, the maximum calculation result data
", and "E4" corresponding to this "3" becomes the pitch to be played next.

Then, in the same way, the next pitch to be played is determined from this "E4", and thereafter performance patterns are sequentially formed based on the frequency data.

In this way, weighting reduces the data to near infinity rlooo
When set to J, the pitch to be played next is determined based only on the frequency data without taking random number data into consideration, and the performance pattern becomes one that is highly necessary for the style of blues music.

Therefore, when weighting data with 1, if the data is set to an appropriate value between rloooJ and "0", the frequency data and the random number data are appropriately taken into consideration, and a piece of music that matches the blues style can be obtained.

In this way, it is possible to automatically compose a piece of music that matches the intended musical style. This can be done in the same way even when another music style is selected using the music style selection device 2111.

In this embodiment, since the weighting of the frequency data and the random number data can be changed, by changing the weighting, it is possible to compose various songs for the same blues, and the frequency data can be used to store multiple musical styles. Because of this, it is possible to compose music in a variety of styles.

In the above embodiment, the weighting between the frequency data and the random number data can be changed, but the weighting may be fixed, and the frequency data stored in the fixed storage device l can be changed into one weight. The amount of frequency data may be not only one octave, but also more or less than one octave.

[Effects of the Invention] As explained in detail below, this invention can produce a certain H'? from a certain pitch. The frequency at which the pitch changes to high is memorized, and based on this frequency and a random number, the pitch to be played next is calculated from the pitch that has been praised, so the change pattern of the rf height is It is possible to create a certain degree of necessity, and it is possible to automatically compose a piece of music that matches the intended style rather than a random piece of music, and even those without musical training can compose many pieces of music. This has the effect of fostering mutual understanding in terms of music education.

[Brief explanation of drawings]

Figure 1 is an overall block circuit diagram of the automatic music composer. 2 and 3 are diagrams showing specific examples of frequency data and random number data, and FIG. 4 is a flowchart of automatic composition processing. 1...Storage device, 2...Random number generator,
3...Arithmetic circuit, 4...Phrase storage device, 8...Variable resistance unit, 11...
- Wind selection device, 12... First sweat determining device. Patent Applicant: Casio Computer Co., Ltd. ζ--・1f Agent: Patent Attorney Machi 1) Toshimasa 1C4 (Σ; ゛Kin A Main Circuit Figure 1 Progress Rate - Evening Iku 1 ()"Ruth" Figure 2 Ran＠Ding゛-Evening A row Figure 3

Claims (3)

[Claims] (1) A storage means for storing the frequency of changes from one pitch to another in the flow of a piece of music, a random number generation means for generating random numbers, and frequency data from the storage means and the random number generation means. 1. An automatic music composition machine comprising: calculation means for calculating the pitch to be played next from a given pitch based on random number data. (2) Claims characterized in that the calculation means weights the frequency data from the storage means and the random number data from the random number generation means, and this weighting is variable. The automatic music composition machine described in paragraph 1. (3) The automatic music composition machine according to claim 1, wherein the storage means has frequency data of a plurality of musical styles, and each frequency data can be selected depending on the musical style.