JP2736557B2 - Electronic musical instrument - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic musical instrument for reading out a musical tone waveform stored in a storage means, and more particularly to an electronic musical instrument for changing a tone color.

2. Description of the Related Art Conventionally, in an electronic musical instrument of the above-mentioned type, there is an electronic musical instrument that changes the timbre as disclosed in, for example, Japanese Patent Application Laid-Open No. 61-124994. In this method, a plurality of types of musical sound waveforms are stored in a storage means, and when reading out the musical sound waveforms from the storage means, a combination of a key range and a musical sound waveform is changed according to a touch of a key.

[Problems to be Solved by the Invention] However, in such an electronic musical instrument, only the timbre is changed in accordance with the touch on the key, and the timbre can be delicately changed. And could not.

It is an object of the present invention to obtain musical tones of essentially different timbres.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides an input means for inputting pitch information representing a pitch, and a plurality of sound ranges obtained by dividing a series of pitches into a plurality of groups. Storage means for storing musical tone waveforms corresponding to the respective groups; and a reading speed at which the musical tone waveforms of the tone range group to which the pitch information input from the input means belongs are generated at the pitch represented by the pitch information. It has reading means for reading and parameter setting means for setting a shift amount for shifting the relationship between the pitch information and the tone range group. Then, with respect to the pitch information input from the input means, the musical tone waveform shifted according to the parameter set by the parameter setting means is read out at a reading speed at which the pitch is expressed by the pitch represented by the pitch information. Is read.

[Operation] When the parameter setting means is not provided, the tone waveform corresponding to the tone range to which the inputted pitch information belongs is read out from the storage means at a reading speed corresponding to the pitch information, and a tone signal is generated. However, according to the present invention, since the parameter setting means is provided, the tone waveform to be read is a tone waveform shifted according to the parameter set by the parameter setting means.

[Embodiment] A keyboard instrument for facilitating the understanding of the embodiment of the present application is firstly described.
This is shown in FIGS. This keyboard instrument has a waveform memory 2 as shown in FIG. As shown in FIG. 4, this waveform memory stores start addresses of AD0, AD1,.
A plurality of musical tone waveforms M0, M1,..., M10 are stored. These musical tone waveforms correspond to the tone range, and the tone range O2 shown in FIG. 3 corresponds to the tone waveform M2, the tone range O3 corresponds to the tone waveform M3,... The tone range O8 corresponds to the tone waveform M8. Of course, the ranges O0, O1, O9, O1 not shown in FIG.
0 corresponds to the tone waveforms M0, M1, M9, and M10, respectively.

The waveform is read from the waveform memory 2 by the address signal generated by the address generating means 4 and supplied to the envelope multiplier 6, where the envelope generating means 8
Multiplied by the envelope signal generated from the
Output from 10. The address generating means 4 outputs the range information (for example, 3 when a key in the range O3 shown in FIG. 3 is depressed) OC generated by the keyboard detecting means 14 in response to the operation of the keyboard 12.
And note name information (information indicating the note name of the key that has been pressed) KC, and further receives parameter information from the shift parameter setting means 16, and determines from the start address determined based on the parameter information and the range information, The tone waveform is read out at the readout speed determined based on the note name information KC.

These means can obtain a plurality of phoneme pieces by operating in a time-division manner, synthesize these phoneme pieces by accumulating means (not shown), and convert them into analog signals by a D / A converter. Output.

FIG. 1 shows a detailed configuration of the address generator 4 and the shift parameter generator 16. The address generating means 4 has a start address converter 18. This is RAM or R
It is a conversion table configured by the OM. The start address converter 18 generates a start address corresponding to the input range information OC. For example, if the input range information OC is 2 representing the range O2, the start address converter 18 generates a start address AD2. is there.

The output of the adder 20 is input to the start address converter 18, and the adder 20 adds the sound range information OC from the key press detection means 14 and the shift parameter from the shift parameter setting means 16. Things.

The shift parameter setting means 16 calculates the shift amount-2,-
The contact 16 to which the signals of 1, 0, +1 and +2 are supplied respectively
For example, when the contact 16f is switched to the contact 16a by a changeover switch having a, 16b, 16c, 16d, 16e and a contact 16f, -2 is supplied to the adder 20 as a shift parameter. Therefore, assuming that the range information OC supplied to the adder 20 at this time is 2 representing the range O2, the range information OC supplied to the start address converter 18 is the range O0 shifted from the range O2 by -2. , And the start address converter 18 generates AD0 as the start address.

The address generating means 4 also has a pitch information converter 22. This is also the same as the start address
This is a conversion table constituted by M or ROM, which generates pitch information for determining the reading speed according to the pitch name information KC supplied from the key press detection means 14.

The start address from the start address converter 18 and the pitch information from the pitch information converter 22 are supplied to an adder 28 via interlocking changeover switches 24 and 26. The changeover switch 24 has two contacts 24a and 24b and a contact 24c. The contact 24a is supplied with a start address from the start address converter 18, and the contact 24b is provided on the output side of the adder 28. The output of the latch 30 is supplied and the contact 24
c is connected to the input side of the adder 28. Selector switch 2
6 also has contacts 26a, 26b and a contact 26c, the signal O is supplied to the contact 26a, the pitch information from the pitch information converter 22 is supplied to the contact 26b, and the contact 26c is an adder. Connected to 28 inputs. These changeover switches 24 and 26
Are switched synchronously, and when the contact 24c of the switch 24 is in contact with the contact 24a, the contact 2 of the switch 26 is
6c contacts the contact 26a. Similarly, when the contact 24c of the changeover switch 24 contacts the contact 24b, the contact 26 of the changeover switch 26 contacts the contact 26b. Although not shown, the changeover switches 24 and 26 are switched in accordance with sampling of key press detection by the key press detection unit 14.

That is, when it is first determined by sampling that the key is pressed, the contacts 24c and 2c of the changeover switches 24 and 26 are
6c is connected to the contacts 24a and 26a. At this time, if the start address from the start address converter 18 is shifted by -2 as described above, and the range of the key pressed is O2 but the range of the key O0 is AD0, this is the changeover switch 24.
Is supplied to the adder 28 via the. At this time, the contact 26c of the changeover switch 26 is connected to the contact 26a to which the 0 signal is supplied.
, The output of the adder 28 is the start address AD0, which is latched by the latch 30.

When the second press of the key is detected by sampling, the contacts 24c and 26c of the changeover switches 24 and 26 are detected.
Is switched to the contacts 24b and 26b, the adder 28 adds the pitch information supplied via the changeover switch 26 to the value latched in the latch 30 via the changeover switch 24. This value is latched by the latch 30. Hereinafter, since the contacts 24c and 26c of the changeover switches 24 and 26 maintain the state of being switched to the contacts 24b and 26, the value of the latch 30 is increased by the value of the pitch information every time sampling is performed. To go. This is supplied to the waveform memory 2 as an address signal.

Therefore, assuming that the start address AD0 is 0 and the pitch information is 2 as shown in FIG.
..,... Are read from the waveform memory 2 and if the pitch information is 3, addresses 0, 3,.
..,... Are read out. Therefore,
The reading speed of the musical tone waveform is changed according to the pitch information.

As described above, in this keyboard instrument, the range information representing the depressed range is shifted according to the parameter information given by the shift parameter means 16, and the start address is determined according to the shifted range information. A tone waveform is read from the start address, and the reading speed is determined according to the pitch information.

An embodiment of the present invention is shown in FIGS. In this embodiment, a fine tone change can be obtained as compared with the above-mentioned keyboard instrument, and as shown in FIG.
a generates a key number KNO of a depressed key of the keyboard 12. The key number KNO is a unique number assigned to each key of the keyboard 12, such as 36 to 95, as shown in FIG. Therefore, when a key having a pitch of C4 is pressed, as shown in FIG. 8, the key pressing detecting means 14a generates a key number 60.

This key number KNO is supplied to reading means, for example, address generating means 4a. The address generating means 4a is supplied to the key range detecting means 32 as shown in detail in FIG. Although the shift parameter is supplied from the shift parameter setting unit 16 to the key range detection unit 32, a state in which the shift parameter is not supplied will be described first for the sake of explanation. The key range detection means 32 detects which key range group the key pressed on the basis of the supplied key number KNO. As shown in FIG. 8, the key area group is an M2 group with a key having a key number KNO of 36 to 47, an M3 group is a key with a key number KNO of 48 to 59, and so on.
... Each of the M6 groups is composed of keys having a key number KNO of 84 to 95. Then, the key number KNO of the highest key of each of the key range groups M2 to M6 is set in the key range detecting means 32 as a split point. This split point can be set arbitrarily. The key range detection means 32 compares the supplied key numbers KNO in ascending order of the split points, and detects which key range group the supplied key numbers KNO belong to. , And outputs data indicating the group. For example, when 42 is supplied as the key number KNO, the key area detection means 32 outputs data 2 indicating that the key area belongs to the key area group M2. This is a start address translator
18 and the start address translator 18
Generates the start address of the tone waveform M2 stored in the storage means, for example, the waveform memory 2. Similarly, when 54 is supplied as the key number KNO, the key range detecting means 32 outputs data 3 indicating that the key number belongs to the key range group M3, and the start address generator 18 detects the start address of the tone waveform M2. Occur.

The output from the key range detecting means 32 is also supplied to a pitch difference detecting means 34. The pitch difference detecting means 34 has a key number KNO
Are also supplied. By the way, the musical tone waveforms M2, M3... M6 stored in the waveform memory 2 are, for example,
The waveforms have the pitches of the keys of key numbers 42, 54,... 90 of M2, M3,. The pitch difference detecting means 34 includes a key number KNO of the tone of the musical tone waveform stored corresponding to each of these tone range groups, and a key number KNO supplied from the key pressing detecting means 14a.
And outputs the difference. For example, key press detection means
Assuming that the key number from 14a is 47, the pitch difference detecting means 34 determines the key number 47 based on the output of the key range detecting means 32 (in this case, 2 representing the range group M2).
Compare with 42 and output +5. Similarly, key press detection means 14
If the key number supplied from a is 36, the pitch difference detecting means 34 compares the key number 42 with the key number 36 because the output of the key range detecting means 32 is 2 in this case as well, Outputs -5. The output of these pitch difference detecting means 34 is a pitch information converter.
22 and a pitch information converter similar to the keyboard instrument described above.
Reference numeral 22 outputs pitch information for determining the reading speed from the waveform memory 2.

The pitch information and the start address are processed by the changeover switches 24 and 26, the adder 28, and the latch 30 in the same manner as in the above-described keyboard instrument, and the tone waveform is read from the waveform memory 2.

In this embodiment, the parameter information from the shift parameter setting means 16 determines the amount by which the split point set in the key range detection means 32 is shifted.
± Can be shifted to either. For example, assuming that the shift amount is +7, the split point of the gamut group M2 shifts from 47 to 54, and similarly, the split points shift to 66, 78, and 90, respectively. Therefore, for example, when the key with the key number 66 is pressed, the key range group before the shift is
Although M4 in tone waveform M4 stored in the waveform memory 2 has occurred at pitch of F ₄ ^#, the key range group after shifting M3
And the tone waveform M3 stored in the waveform memory 2 is changed to F ₄
Occurs at the pitch ^# . In the case of such a shift, the processing of the key group of the key numbers 36 to 42 becomes a problem. In that case, the key range 36 to the key number 54 may be set as the musical range group M2, or the waveform memory 2 Range group
If there is room to store the tone waveform of M1, key numbers 36 to 47 may be assigned to the range group M1. In this case, when the parameter amount from the shift parameter setting means 16 is 0, each key and the waveform in the waveform memory have a relationship as shown in FIG. Then, the relationship between each key and the waveform in the waveform memory as shown after the shift shown in the figure is obtained, and the tone becomes slightly brighter. Although the effect of the musical tone cannot be said unconditionally, since the pitch is set to be high, the musical tone generally seems to be brighter than before the shift.

As described above, in this embodiment, since a fine shift amount can be set for each key, it is possible to adjust the tone more finely than the above-mentioned keyboard musical instrument.

In the above embodiment, the present invention is applied to a keyboard instrument.
In addition, the present invention can be applied to an electronic string instrument such as a guitar synthesizer, a sequencer, and the like.

[Effects of the Invention] As described above, according to the present invention, since the relationship between the pitch information and the read musical tone waveform is shifted by the shift parameter, it is possible to easily obtain phoneme pieces having completely different formants.

[Brief description of the drawings]

FIG. 1 is a block diagram of a main part of a keyboard instrument for facilitating understanding of the present invention, FIG. 2 is a block diagram of the entire keyboard instrument, and FIG. FIG. 4 is a diagram showing a relationship between musical tone waveforms stored in a waveform memory of the keyboard instrument, FIG. 5 is an explanatory diagram of a read state of waveform data in the keyboard instrument, and FIG. 6 is an electronic device according to the present invention. FIG. 7 is a block diagram of a main part of the embodiment of the musical instrument, FIG. 8 is a block diagram of a main part of the embodiment, and FIG. 8 is a diagram showing a relationship between each key and a range of the embodiment. 2 ... waveform memory, 4, 4a ... address generation means, 14,
14a Key-press detection means.

Claims (1)

(57) [Claims] An input unit for inputting pitch information representing a pitch; a storage unit for storing a musical tone waveform corresponding to each of a plurality of tone range groups obtained by dividing a series of pitches into a plurality of groups; Reading means for reading out the musical tone waveform of the range group to which the pitch information input from the input means belongs at a reading speed for generating the pitch at the pitch represented by the pitch information; and shifting the relationship between the pitch information and the pitch range group. Parameter setting means for setting a shift amount to be shifted, and for the pitch information input from the input means, the tone waveform shifted corresponding to the parameter set by the parameter setting means, An electronic musical instrument characterized by reading at a reading speed that generates sound at a pitch represented by pitch information.