Musical tone signal generating apparatus

A musical tone signal generating apparatus is provided for an keyboard electronic musical instrument. This apparatus provides a waveform memory capable of storing musical tone waveform data concerning plural musical tone waveforms each having a different cycle such as a different tone color. The musical tone waveform data can include plural sampling data concerning the musical tone waveform which is picked up by a microphone, for example. Each musical tone waveform is divided into several segments each designated by front (or head) and end addresses. By shifting designation timings of addresses between the front and end addresses of the predetermined segment, two series of musical tone waveform data can be obtained based on the musical tone waveform of the same predetermined segment from the waveform memory. By mixing two series of musical tone waveform data together by a desirable mixing rate, a smooth musical tone waveform corresponding to well-mixed musical tone waveform data can be obtained even when the musical tone waveform of the predetermined segment is repeatedly read out. Then, the apparatus generates a musical tone signal indicative of such smooth musical tone waveform, whereby it is possible to eliminate unnatural portions to be heard in the repeatedly generated musical tone.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a musical tone signal generating 
apparatus, and more particularly to a musical tone signal generating 
apparatus which generates a musical tone signal corresponding to musical 
tone waveform data pre-stored in a memory, wherein the musical tone 
waveform data indicates a musical tone waveform including plural waveforms 
each having a different cycle. 
2. Prior Art 
Conventionally, the well-known musical tone signal generating apparatus 
provides a memory for pre-storing the musical tone waveform data whose 
read-out operation is controlled by address designation. This apparatus 
repeatedly reads out the musical tone waveform data in the segment 
designated by a front address and an end address from such memory to 
thereby generate the musical tone signal corresponding to the read musical 
tone waveform data. However, in the case where this conventional apparatus 
repeatedly reads out the musical tone waveform data within the 
predetermined segment from the continuous musical tone waveform data 
indicative of the musical tone waveform which is originally picked up from 
an external musical instrument, the tone color is not varied smoothly at a 
time when the conventional apparatus begins to read out the musical tone 
waveform data at the front portion of segment after reading out the 
musical tone waveform data at the end portion of segment. For this reason, 
there must be an unnatural portion to be heard in the generated musical 
tone. 
Therefore, recently, the following musical tone generating apparatus is 
developed. This apparatus, as disclosed in Japanese Patent Laid-Open 
Publication No. 59-188697 (i.e., U.S. Pat. No. 4,520,708), makes new 
musical tone waveform data mainly based on the musical tone waveform data 
indicative of the original musical tone waveform within the repeatedly 
reading segment and by use of the weighted addition, whereby this new 
musical tone waveform data is stored in the memory. More specifically, the 
musical tone waveform data at the front portion of certain segment is 
added to musical tone waveform data at the end portion of certain segment 
as weighted-addition data. Thus, at the time when the apparatus begins to 
read out the musical tone waveform data at the front portion of segment 
after reading out the musical tone waveform data at the end portion of 
segment, there is no unnatural portion to be heard in the generated 
musical tone. Accordingly, it is possible to obtain the musical tone 
signal whose tone color is smoothly varied, for example. 
However, in the above known apparatus, it is necessary to process the 
original tone waveform picked up externally before storing the musical 
tone waveform data in the memory. Therefore, this apparatus is 
disadvantageous in that such processing is troublesome and the special 
device for such processing must be required. Especially, it is difficult 
to process this musical tone waveform data within the musical instrument. 
Therefore, it is impossible to apply the foregoing musical tone generating 
apparatus as published in Japan to the musical instrument which picks up 
the desirable external tone before the performance and immediately 
thereafter uses the musical tone waveform data concerning such picked-up 
external tone for the performance. In such case, it is impossible to 
obtain the musical tone signal whose tone color is varied smoothly so that 
there will not be unnatural portion to be heard in the generated musical 
tone, for example. 
In addition, the foregoing published apparatus processes the musical tone 
waveform data at the end portion of segment by use of the musical tone 
waveform data at the front portion of segment. For this reason, the data 
at the front and end portions of segment must be fixed. Hence, this 
apparatus can repeatedly read out the same musical tone waveform data 
only. Due to such reading process, the tone color of the generated musical 
tone must be fixed. Accordingly, there is another problem in that it is 
impossible to obtain the musical tone having the complicated and variable 
tone colors. 
SUMMARY OF THE INVENTION 
Accordingly, it is a primary object of the present invention to provide a 
musical tone signal generating apparatus which repeatedly reads out the 
musical tone waveform data of the predetermined segment, wherein the 
unnatural portion to be heard in the generated musical tone can be 
eliminated when repeatedly reading out the musical tone waveform data 
without processing the original musical tone waveform data to be 
externally picked up in advance. 
In a first aspect of the present invention, there is provided a musical 
tone signal generating apparatus comprising: 
(a) memory means for storing musical tone waveform data indicative of 
plural musical tone waveforms each having a different cycle, the musical 
tone waveform being divided into several segments each designated by a 
front address and an end address, wherein a reading operation of the 
memory means is controlled by designating addresses; 
(b) first reading means for repeatedly reading out the musical tone 
waveform data of a predetermined segment from the memory means by 
repeatedly designating addresses between the front and end addresses 
corresponding to the predetermined segment, so that the musical tone 
waveform data read by the first reading means is outputted as first 
musical tone waveform data; 
(c) second reading means for repeatedly reading out the musical tone 
waveform data of the predetermined segment by shifting designation timings 
of the addresses between the front and end addresses corresponding to the 
predetermined segment with a predetermined shifting time, so that the 
musical tone waveform data read by the second reading means is outputted 
as second musical tone waveform data; and 
(d) mixing means for mixing the first musical tone waveform data and the 
second musical tone waveform data together by a mixing rate, 
whereby a musical tone signal is generated in response to mixed musical 
tone waveform data outputted from the mixing means. 
In a second aspect of the present invention, there is provided a musical 
tone signal generating apparatus comprising: 
(a) a waveform memory for storing musical tone waveform data indicative of 
plural musical tone waveforms each having a different cycle, the musical 
tone waveform being divided into several segments each designated by a 
front address and an end address, wherein a reading operation of the 
waveform memory is controlled by designating addresses; 
(b) detecting means for detecting operations of manual performance controls 
provided at an electronic musical instrument; 
(c) address designating means for designating two series of addresses based 
on a time sharing system, by which two series of musical tone waveform 
data are read from the waveform memory; 
(d) mixing rate control means for controlling a mixing rate by which the 
two series of musical tone waveform data are mixed together; and 
(e) means for mixing the two series of musical tone waveform data by the 
mixing rate, 
whereby a musical tone signal is generated in response to mixed musical 
tone waveform data. 
In a third aspect of the present invention, there is provided a musical 
tone signal generating apparatus comprising: 
(a) a waveform memory for storing musical tone waveform data indicative of 
plural musical tone waveforms each having a different cycle, the musical 
tone waveform being divided into several segments each having two edges 
which are respectively designated by a head address and an end address, 
wherein a reading operation of the waveform memory is controlled by 
designating the head and end addresses; 
(b) detecting means for detecting operations of manual performance controls 
provided at an electronic musical instrument; 
(c) address designating means capable of designating desirable two pairs of 
head and end addresses based on a time sharing system, by which two series 
of musical tone waveform data both concerning the same segment of the 
musical tone waveform are read from the waveform memory, wherein a 
predetermined phase difference is set between the desirable two pairs of 
head and end addresses; 
(d) mixing rate control means for controlling a mixing rate in accordance 
with the desirable two pairs of head and end addresses; and 
(e) means for mixing the two series of musical tone waveform data by the 
mixing rate, 
whereby a musical tone signal is generated in response to mixed musical 
tone waveform data.

DESCRIPTION OF A PREFERRED EMBODIMENT 
[A] BASIC OPERATION OF THE PRESENT INVENTION 
The musical tone signal generating apparatus according to the present 
invention comprises: 
a waveform memory for storing musical tone waveform data; 
first reading means for repeatedly reading the musical tone waveform data 
from the waveform memory as first musical tone waveform data by repeatedly 
designating the addresses between the front address and end address both 
designating the predetermined segment; 
second reading means for repeatedly reading the musical tone waveform data 
from the waveform memory as second musical tone waveform data by shifting 
the designation timings of the addresses between the front and end 
addresses with the predetermined delay time; and 
mixing means for mixing the first musical tone waveform data and the second 
musical tone waveform data together. 
In the above-mentioned configuration, the designation timings of addresses 
of the first reading means are delayed from those of the second reading 
means by the predetermined delay time. Therefore, the phase of first 
musical tone waveform data is different from that of second musical tone 
waveform data. Hence, when the first reading means starts to read out the 
musical tone waveform data at the front portion of segment as the first 
musical tone waveform data after reading out the musical tone waveform 
data at the end portion of segment, the second reading means is now 
reading the musical tone waveform data at the middle portion of segment a 
the second musical tone waveform data. At this time, these first and 
second musical tone waveform data are mixed together, and then the mixed 
musical tone waveform data is outputted. In this case, the first musical 
tone waveform data indicates a discontinuous envelope, while the second 
musical tone waveform data indicates a continuous envelope. For this 
reason, such discontinuity of first musical tone waveform data is smoothed 
by the continuous second musical tone waveform data. Thus, the tone color 
of generated musical tone can be varied smoothly, so that it is possible 
to obtain the musical tone signal without the unnatural portion to be 
heard in the generated musical tone. 
In addition, the mixing rate of first and second musical tone waveform data 
can be controlled such that the mixing rate will be gradually increased at 
the front portion of segment but the mixing rate will be gradually 
decreased at the end portion of segment. In this case, when the musical 
tone waveform data at the end portion of segment is varied to that at the 
front portion of segment, the mixing rate is controlled to be decreased. 
Due to such control, the tone color variation can be further smoothed. 
[B] ELECTRIC CONFIGURATION OF AN EMBODIMENT OF THE PRESENT INVENTION 
Next, description will be given with respect to the electric configuration 
of an embodiment of the present invention, wherein FIGS. 1A and 1B are 
block diagrams showing the keyboard electronic musical instrument which 
adopts the musical tone signal generating apparatus according to an 
embodiment of the present invention. 
This keyboard electronic musical instrument sequentially reads out the 
musical tone waveform data stored in a waveform memory 1 (shown in FIG. 
1B) in response to operations of manual performance controls such as keys 
of keyboard, so that it generates the musical tone signal corresponding to 
the read data. This electronic musical instrument provides a clock 
generating portion 2 for generating a clock signal for controlling the 
operation timings thereof; a manual control detecting portion 3 for 
detecting the operation of foregoing performance manual control; an 
address designating portion 4 for controlling two series of musical tone 
waveform data by designating the address of waveform memory 1 with 
time-sharing system; a mixing rate control signal generating portion 5 for 
generating a mixing rate control signal MIXS for controlling the mixing 
rate of two series of musical tone waveform data to be read from the 
waveform memory 1; and an output circuit portion 6 for mixing the two 
series of musical tone waveform data together in response to the foregoing 
mixing rate control signal MIXS to thereby output the mixed data. 
The waveform memory 1 comprises a read-only memory (ROM) and a 
random-access memory (RAM) as shown in FIG. 2. The storing area of ROM is 
divided into plural middle areas TC1, TC 2, ..., TCm in response to tone 
color selectors each designating each of tone colors of piano, violin and 
the like, and each middle area is further divided into plural small areas 
KC1, KC2, ..., KCn in response to tone areas within the keyboard (where 
numbers m and n denote arbitrary natural numbers). Each small area 
pre-stores the waveform data consisting of a plenty of sampling data each 
indicating an each instantaneous value of the musical tone waveform whose 
magnitude is continuous from the rising portion of the musical tone as 
shown in FIG. 3. Similar to this ROM, the storing area of RAM is also 
divided into middle areas SMP1 and SMP2, and each middle area is further 
divided into plural small areas KC1, KC2, ..., KCn. Each small area stores 
the waveform data consisting of the foregoing sampling data concerning the 
desirable external tone which is externally picked up by the player. In 
the present embodiment, each small area stores such waveform data by every 
tone area. 
For this reason, the waveform memory 1 (shown in FIG. 1B) is connected with 
a writing control circuit 11 by which the waveform data concerning the 
foregoing external ton is written into the waveform memory 1. In this 
case, a microphone 12 picks up the external tone and then converts such 
picked-up external tone into an analog signal This analog signal is 
converted into a digital signal in an analog-to-digital (A/D) converter 
14. Then, this digital signal is supplied to the writing control circuit 
11. In addition, this circuit 11 is supplied with a key code KC and a tone 
color selecting signal TC which are respectively supplied from a 
key-depression detecting circuit 33 and a tone color selection detecting 
circuit 35 (shown in FIG. 1A). In response to these key code KC and tone 
color selecting signal TC, the writing control circuit 11 designates the 
storing area for storing the waveform data concerning the external tone in 
the RAM within the waveform memory 1. 
The clock generating portion 2 includes a master clock generator 21, a 1/2 
frequency divider 22 and an inverter circuit 23. This clock generating 
portion 2 generates a first clock signal C having high frequency, an 
inverted first clock signal C and a second clock signal 2C having double 
frequency of first clock signal C. 
The manual control detecting portion 3 provides a key switch circuit 31 
including plural key switches each corresponding to each key of keyboard, 
and a tone color selecting switch circuit 32 including plural tone color 
selecting switches each corresponding to each tone color selector. The key 
switch circuit 31 is connected with the key-depression detecting circuit 
33 which detects open/close operations of each key switch within the key 
switch circuit 31 to thereby detect the key-depression of each key of 
keyboard. This key-depression detecting circuit 33 outputs the key code 
indicative of the depressed key and a key-on signal KON whose logical 
value changes to "1" at the key-depression timing but changes to "0" at 
the key-release timing. Moreover, this circuit 33 differentiates the 
rising portion of key-on signal KON to thereby generate a key-on pulse 
signal KONP whose logical value turns to "1" at the key-depression timing. 
Based on the key code KC supplied from the key-depression detecting 
circuit 33, a note clock generator 34 generates and then outputs a note 
clock signal Cn having the frequency which is proportional to the pitch 
frequency of depressed key. For example, the frequency of this note clock 
signal Cn is set sufficiently higher than the pitch frequency of depressed 
key. 
Meanwhile, the tone color selection detecting circuit 35 detects the 
open/close operations of the tone color selecting switch within the tone 
color selecting switch circuit 32 to thereby detect the operation of tone 
color selector. Based on the operation of tone color selector, this 
circuit 35 outputs the tone color selecting signal T indicative of the 
selected tone color. 
The address designating portion 4 provides an accumulator 41 coupled to the 
note clock generator 34. This accumulator 41 is reset by a pulse signal 
which is supplied to its reset terminal R via an OR circuit 42. The 
accumulator 41 accumulates the predetermined values by the timing 
designated by the note clock signal Cn from the note clock generator 34 
which is supplied to a clock input CK thereof. Based on such accumulation, 
the accumulator 41 outputs a relative address signal corresponds to the 
phase of musical tone signal waveform shown in FIG. 3. The value of this 
relative address signal is varied by the rate proportional to the pitch 
frequency of depressed key so that it will indicate each address of small 
area within the waveform memory 1. Next, an adder 43 adds the relative 
address signal from the accumulator 41 with an address signal from a start 
address memory 44 to thereby calculate an absolute address of the waveform 
memory 1. Then, the signal indicative of the absolute address is supplied 
to a first input ("1") of a selector 45 as a first address signal AS1. 
The start address memory 44 is configured by the RAM. This memory 44 stores 
attack start address data AD0 (see FIG. 3) by each small area of the 
waveform memory 1, wherein this data AD0 indicates the absolute address at 
which the sampling data concerning the head address thereof, i.e., the 
tone-generation start timing of the musical tone is stored. In addition, 
the memory 44 stores repeat start address data AD1 (see FIG. 3) by each 
small area of the waveform memory 1, wherein this data AD1 indicates the 
absolute address at which the sampling data corresponding to the start 
position for repeatedly reading the musical ton waveform data is stored. 
The reading of these data AD0 and AD1 is controlled by the key code KC, 
the tone color selecting signal TC and a repeat start signal ST. The 
repeatedly reading of the waveform data is designated when the repeat 
start signal ST takes the value "1", while it is designated that the 
repeatedly reading of the waveform data is stood by when the signal ST 
takes the value "0". Therefore, when the repeat start signal ST takes the 
value "0", the reading of the attack start address data AD0 is designated. 
When the repeat start signal ST takes the value "1", the reading of the 
repeat start address data AD1 is designated. 
The first address signal AS1 from the adder 43 is supplied to a second 
input of a comparator 46, while an end address signal from an end address 
memory 47 is supplied to a first input of comparator 46. When the end 
address signal coincides with the first address signal AS1, the comparator 
46 outputs a coincidence signal to a delay circuit (D) 48. Under control 
of the first clock signal C, the delay circuit 48 delays the coincidence 
signal by one-bit time. This delayed coincidence signal and the key-on 
pulse signal KONP are both supplied to the OR circuit 42, whose output is 
then supplied to the reset terminal R of the accumulator 41. In addition, 
the delayed coincidence signal from the delay circuit 48 is also supplied 
to a set terminal S of a flip-flop circuit 51. This flip-flop 51 outputs 
the foregoing repeat start signal ST from an output terminal Q thereof. 
Further, the key-on pulse signal KONP is supplied to a reset terminal R of 
the flip-flop 51. 
The end address memory 47 is also configured by the RAM. This memory 47 
stores attack end address data (AD1-1) (see FIG. 3) by each small area of 
the waveform memory 1, wherein the value of this data (AD1-1) is smaller 
than that of repeat start address data AD1 by "1" so that this data 
(AD1-1) corresponds to the absolute address indicative of the end portion 
of attack portion. In addition, the memory 47 stores repeat end address 
data AD3 (see FIG. 3) by each small area of the waveform memory 1, wherein 
this data AD3 indicates the absolute address at which the sampling data 
corresponding to the end position of repeatedly reading the musical tone 
waveform data is stored. The readings of these data (AD1-1) and AD3 are 
controlled by the tone color selecting signal TC, the key code KC and the 
repeat start signal ST. In the present embodiment, the reading of attack 
end address data (AD1-1) is designated when the repeat start signal ST 
takes the value "0", while reading of repeat end address data AD3 is 
designated when this signal takes the value "1". 
In order to write and rewrite several data in these start address memory 44 
and end address memory 47, a start/end address setting unit 52 and a 
writing control circuit 53 are provided. The start/end address setting 
unit 52 provides a ten-key unit and writing control switches, so that this 
unit 52 outputs address data concerning the memories 44 and 47 and also 
outputs the data to be written in the memories 44 and 47. Under control of 
this unit 52, the writing operations of these memories 44 and 47 ar 
designated. In accordance with such designation by the unit 52, the 
writing control circuit 53 controls the data to be written into the 
memories. 
Further, outputs (A and B) of these memories 44 and 47 are supplied to a 
subtractor 54. This subtractor 54, a divider 55 and an adder 56 configures 
a circuit for computing central address data AD2 corresponding to a 
central value between the values of repeat start address data AD1 and 
repeat end address data AD3. More specifically, the subtractor 54 
subtracts the repeat start address data AD1 from the repeat end address 
data AD3 to thereby obtain the subtraction result (AD3-AD1), which is then 
supplied to the divider 55 wherein such subtraction result is divided by 
two. This divider 55 outputs its divide result (AD3-AD1)/2 to a first 
input of the adder 56, while the repeat start address data AD1 is supplied 
to a second input of the adder 56. This adder 56 adds these data AD1 and 
(AD3-AD1)/2 together to thereby obtain data (AD3+AD1)/2, which is then 
outputted to a first input of a comparator 57 as the central address data 
AD2. 
On the other hand, the first address signal AS1 is supplied to a second 
input of the comparator 57. Then, the comparator 57 outputs a selection 
signal SEL3 based on its comparison result. More specifically, the value 
of this selection signal SEL3 turns to "1" in the case where the value of 
first address signal AS1 is smaller than the value of central address data 
AD2. In other cases, the value of selection signal SEL3 turns to "0". This 
selection signal SEL3 is outputted to a selection control terminal SL of a 
selector 58. Thus, the selector 58 selectively outputs a signal supplied 
to a first input ("1") thereof as a third address signal AS3 when the 
selection signal SEL3 takes the value "1", while the selector 58 
selectively outputs another signal supplied to a second input ("0") 
thereof as the third address signal AS3 when the selection signal SEL3 
takes another value "0". These first and second inputs of selector 58 are 
respectively supplied with outputs of an adder 61 and a subtractor 62. The 
adder 61 inputs and then adds the first address signal AS1 and the signal 
(indicative of the data [AD3-AD1]/2=AD2-AD1) together to thereby generate 
an address signal whose phase is a half period of the repeating segment 
forward as compared to the phase of first address signal AS1. The 
subtractor 62 subtracts the value of data (AD3-AD1)/2 outputted from the 
divider 55 from the value of first address signal AS1 to thereby generate 
another address signal whose phase is a half period of the repeating 
segment behind as compared to the phase of first address signal AS1. 
Meanwhile, the foregoing comparator 57 outputs a coincidence signal to a 
first input of an AND circuit 63, wherein the value of this coincidence 
signal turns to "1" when the value of first address signal AS1 coincides 
with the value of central address data AD2. On the other hand, the repeat 
start signal ST from the flip-flop 51 is supplied to a second input of 
this AND circuit 63. Then, the output of AND circuit 63 is supplied to a 
reset terminal R of a flip-flop 64. In addition, the key-on pulse signal 
from the key-depression detecting circuit 33 is supplied to a set terminal 
S of this flip-flop 64. This flip-flop circuit 64 supplied its output from 
a terminal Q thereof to a selection control terminal SL of a selector 65 
as a selection signal SEL2. This selector 65 is also configured as similar 
to the foregoing selector 58. More specifically, the selector 65 
selectively outputs the first address signal AS1 supplied to the first 
input ("1") thereof as the second address signal AS2 when the selection 
signal SEL2 takes the value "1", while the selector 65 selectively outputs 
the third address signal AS3 supplied to the second input ("0") thereof as 
the second address signal AS2 when the selection signal SEL2 takes the 
value "0". Such second address signal AS2 is outputted to a second input 
("0") of selector 45. 
This selector 45 is also configured as similar to other selectors 58 and 
65. In addition, the first clock signal C is supplied to a selection 
control terminal SL of selector 45 as its selection signal. More 
specifically, the selector 45 selectively outputs the first address signal 
AS1 supplied to the first input ("1") thereof when its selection signal 
takes the value "1", while the selector 45 selectively outputs the second 
address signal AS2 supplied to the second input ("0") thereof when its 
selection signal takes the value "0". Such selective output of the 
selector 45 is supplied to the waveform memory 1 (shown in FIG. 1B) as an 
output address signal AS0. Since the first clock signal C is supplied to 
the selector 45 as the selection signal, one of the first address signal 
AS1 and second address signal AS2 is selectively outputted by a half 
period of first clock signal C based on time sharing system as the output 
address signal AS0. 
In FIG. 1B, the mixing rate control signal generating portion 5 provides an 
arithmetic logical unit 71. The divider 55 (see FIG. 1A) outputs data X 
having the value (AS2-AS1) indicative of a half period of the repeating 
segment. This data X is supplied to the arithmetic logical unit 71. 
Meanwhile, the output of this unit 71 has a variety range 2.sup.M. The 
arithmetic logical unit 71 operates a calculation of K.multidot.2.sup.M /X 
to thereby obtain a increment value which is in inverse proportion to the 
value corresponding to the period of repeating segment. In this 
calculation, the coefficient K is set as the proportional constant by 
which the value of mixing rate control signal MIXS will be increased to 
the maximum value "2.sup.M -1" when the increment values are accumulated 
by every period of the note clock signal Cn in a half period of the 
repeating segment. In addition, the constant M means the bit number of an 
adder 72, a latch circuit 73 and an inverter 76 as well as the bit number 
of mixing rate control signal MIXS. 
The adder 72 and latch circuit 73 configures an accumulator to which the 
increment value outputted from the arithmetic logical unit 71 is supplied. 
The adder 72 adds the increment value with the output value of latch 
circuit 73, and then the addition result thereof is supplied to the latch 
circuit 73. In addition, the adder 72 generates and outputs a carry signal 
CO to a first input of OR circuit 74 so that this carry signal CO will be 
supplied to a reset terminal R of the latch circuit 73. Meanwhile, the 
repeat start signal ST from the flip-flop circuit 51 is inverted by an 
inverter 75, so that such inverted signal is supplied to a second input of 
OR circuit 74. Thus, the latch circuit 73 is reset when the signal 
supplied to its reset terminal R takes the value "1", while the latch 
circuit 73 latches the addition result of the adder 72 every time the note 
clock signal Cn is supplied to its clock input CK. As a result, the output 
of latch circuit 73 has the value which varies between "0" and "2.sup.M 
-1" by every half period of the repeating segment. 
Then, the data of M bits outputted from the latch circuit 73 is supplied to 
a first input of an inverter unit 76 which is configured by an exclusive 
OR gate. On the other hand, a signal outputted from an output terminal Q 
of a flip-flop 77 is supplied to a second input of the inverter unit 76. 
This inverter unit 76 outputs the input data thereof as it is when this 
signal supplied to the second input thereof takes the value "0". When this 
signal takes the value "1", the inverter unit 76 inverts the value of 
every bit in its input data and then outputs such inverted data. 
Meanwhile, the inverted signal outputted from the inverter 75 is supplied 
to a reset terminal R of the flip-flop circuit 77, while the carry signal 
CO from the adder 72 is supplied to an inversion input terminal T of the 
flip-flop circuit 77. When the value of repeat start signal ST is varied 
to "1", the reset state of flip-flop circuit 77 is released, so that the 
operation of the flip-flop circuit 77 is controlled to be inverted by 
every half period of the repeating segment under effect of the carry 
signal CO. Thus, as shown in FIG. 4, the waveform of mixing rate control 
signal MIXS is varied as a triangular wave by every period of the 
repeating segment. 
Next, in the output circuit portion 6, the first and second series of 
waveform data read from the waveform memory 1 are spatially separated, and 
then an interpolation corresponding to the mixing rate control signal MIXS 
is operated on the separated waveform data. In this output circuit portion 
6, a delay circuit 81 and a multiplier 82 is provided for the first series 
of waveform data, while only a multiplier 83 is provided for the second 
series of waveform data. The delay circuit 81 delays the waveform data by 
a half period of the first clock signal C based on the second clock signal 
2C supplied thereto. Then, the multiplier 82 multiplies the value of the 
delayed waveform data and the value of mixing rate control signal MIXS 
together. On the other hand, the multiplier 83 multiplies the value of 
waveform data and a value of output signal of an inverter circuit 84 
together. This inverter circuit 84 is configured by plural inverters whose 
number corresponds to the bit number M. More specifically, the inverter 
circuit 84 inverts every bit value of the mixing rate control signal MIXS 
to thereby output an inverted mixing rate control signal MIXS (i.e., one's 
complement of the mixing rate control signal MIXS) as shown by the dotted 
line in FIG. 4. 
Thereafter, the adder 85 adds the multiplication results of the multipliers 
82 and 83 together, so that the addition result to be obtained is supplied 
to a latch circuit 86. This latch circuit 86 latches the mixed waveform 
data outputted from the adder 85 in synchronism with the inverted first 
clock signal C. Then, the latch circuit 85 outputs the latched waveform 
data by every latter half period of the first clock signal C. 
The output (i.e., waveform data signal) of latch circuit 86 is supplied to 
a first input of multiplier 87, while an envelope waveform signal 
outputted from an envelope generating circuit 88 is supplied to a second 
input of multiplier 87. Thus, the multiplier 87 multiplies the above 
waveform data signal and envelope waveform signal together. In response to 
the key-on signal KON from the key-depression detecting circuit 33, the 
envelope generating circuit 88 generates the envelope waveform signal 
indicative of an amplitude envelope waveform of the musical tone to be 
generated. In addition, the envelope generating circuit 88 is also 
supplied with the key code KC from the key-depression detecting circuit 33 
and the tone color selection signal TC from the tone color selection 
detecting circuit 35. Thus, the waveform of the envelope waveform signal 
outputted from the envelope generating circuit 88 can be controlled to be 
varied in response to the selected ton color and selected tone area of 
musical tone. 
The digital output of multiplier 87 is converted into an analog signal in a 
digital-to-analog (D/A) converter 91, and then such analog signal is 
supplied to a sound system 92. The sound system 92 includes an amplifier 
and a speaker, so that the sound system 92 generates the musical tone 
corresponding to the analog signal supplied thereto. 
[C] OPERATION OF EMBODIMENT 
Next, description will be given with respect to the operation of the 
present embodiment. 
In the case where the player wants to utilize the desirable external tone 
in the performance, the player operates the tone color selectors so that 
the middle area of waveform memory 1 (i.e., either one of the middle areas 
SMP1 and SMP2 provided in the RAM shown in FIG. 2) will be designated. In 
addition, by depressing the keys of keyboard, the corresponding small 
areas within the designated middle area (i.e., the small areas KC1, KC2, 
..., KCn provided within the RAM shown in FIG. 2) can be designated. After 
these operations, the external tone is picked up by the microphone 12. 
This picked-up external tone is converted into the digital signal 
consisting of sample data in the A/D converter 14. Then, under control of 
the writing control circuit 11, such sample data is written into the small 
area within the waveform memory 1. After this writing operation, the 
player sequentially varies and then designates the small areas within the 
designated middle area by operating the keyboard so that plural sample 
data each having the different tone pitch are respectively written into 
the different small areas. By repeating such operations, several sampling 
data concerning the external tones having several tone areas will be 
written into the waveform memory 1. This repeating operations may not be 
required when the external tones having the different tone areas are not 
required, or when it is impossible to write the sampling data concerning 
plural external tones because the waveform memory provides only one small 
area. 
Next, the player designates the repeating segment of the waveform data 
which are stored in the waveform memory 1. In such case, the player can 
designate the waveform data by the operations of tone color selectors and 
keyboard, wherein each waveform data is stored in the waveform memory 1 by 
each tone color and each tone area (or key area). After designating the 
waveform data, the player inputs the values of the repeat start address 
data AD1 and repeat end address data AD3 by use of the start/end address 
setting unit 52. Then, the writing control circuit 53 calculates the 
attack end address data (AD1-1) base on the inputted repeat start address 
data AD1. These data AD1 and (AD1-1) are written into the start address 
memory 44, while the data AD3 and (AD1-1) are written into the end address 
memory 47. In this case, the writing addresses of these memories 44 and 47 
are designated by the tone color selecting signal TC from the tone color 
selection detecting circuit 35 and the key code KC from the key-depression 
detecting circuit 33. Incidentally, the attack start address data AD0 is 
automatically determined in response to the divided areas of waveform 
memory 1. This data AD0 is written at the initial setting of the 
electronic musical instrument. At this initial setting, the values of 
address data AD1, AD3 and AD1-1 are respectively set as normal values by 
the player. As a result, the present embodiment can save much time and 
labor because the settings can be completed by only setting the repeating 
segment concerning the waveform data to be varied. 
After the above-mentioned preparation, when the player operates the tone 
color selectors and keyboard to thereby start the performance of 
electronic musical instrument, the operation of tone color selector is 
detected by the tone color selecting switch circuit 32 and tone color 
selection detecting circuit 35, so that this circuit 35 generates the tone 
color selecting signal TC. On the other hand, the key-operations of the 
keyboard are detected by the key switch circuit 31 and key-depression 
detecting circuit 33. Thus, the key-depression detecting circuit 33 
outputs the key code KC indicative of the depressed key, the key-on signal 
KON and key-on pulse signal KONP, wherein the levels of these signals KON 
and KONP both rise up to "1" level at the key-depression timing. 
Hereafter, description will be given with respect to the generation of 
musical tone signal in response to the performance by referring to the 
time chart shown in FIG. 4. In FIG. 4, the moment when the key of the 
keyboard is depressed is designated by TO. 
Due to the key-depression, the note clock generator 34 outputs the note 
clock signal Cn corresponding to the key code KC to the accumulator 41. 
After being reset by the key-on pulse signal KONP, the accumulator 41 
generates a relative address signal whose value varies by a rate 
corresponding to the pitch frequency of the depressed key in the keyboard. 
In addition, this key-on pulse signal KONP resets the flip-flop 51 at the 
key-depression timing, so that the level of repeat start signal ST 
outputted from the flip-flop circuit 51 falls down to "0" level. As a 
result, the start address memory 44 outputs the attack start address data 
AD0 and the end address memory 47 outputs the attack end address data 
(AD1-1), wherein these two data concern the selected tone color and the 
tone area of depressed key which are respectively indicated by the tone 
color selecting signal TC and the key code KC. Then, the adder 43 adds the 
value of attack start address data AD0 with the value of relative address 
signal from the accumulator 41 to thereby generate the first address 
signal AS1. This first address signal AS1 indicates the absolute address 
for designating the address of waveform data W1 in the attack portion (see 
FIGS. 3 and 4), wherein this absolute address is set between the addresses 
indicated by the data AD0 and AD1. 
Meanwhile, the key-on signal KON sets the flip-flop circuit 64 at this 
time, so that this flip-flop circuit 64 outputs the selection signal SEL2 
having "1" level to the selector 65. Due to this selection signal SEL2, 
the selector 65 supplies the first address signal AS1 to the second input 
("0") of selector 45 as the second address signal AS2. At this time, the 
first address signal AS1 from the adder 43 is also directly supplied to 
the first input ("1") of selector 45. Thus, the selector 45 supplies the 
output address signal AS0 to the waveform memory 1 as the first address 
signal AS1 in the whole period (including the former half period and 
latter half period) of the first clock signal C. 
Under the above-mentioned operations, the waveform data W1 corresponding to 
the attack portion of musical tone waveform is read from the waveform 
memory 1 as first and second series of waveform data in both of the former 
half period and latter half period of the first clock signal C. Then, the 
waveform data W1 which is outputted as the first series of waveform data 
is delayed by a half period of the first clock signal C in the delay 
circuit 81, and such delayed waveform data is multiplied by the mixing 
rate control signal MIXS in the multiplier 82. In addition, the waveform 
data W1 which is outputted as the second series of waveform data is 
directly supplied to the multiplier 83 wherein this waveform data is 
multiplied by the inverted mixing rate control signal MIXS. For this 
reason, the mixing rate control signal MIXS indicates the mixing rate of 
the first series of waveform data, while the inverted mixing rate control 
signal MIXS indicates the mixing rate of the second series of waveform 
data. Thereafter, these two multiplication results are added together in 
the adder 85, whose output is then latched in the latch circuit 86 by the 
timing of latter half period of the first clock signal C. Meanwhile, the 
repeat start signal ST having "0" level is inverted by the inverter 75, 
and then the inverted repeat start signal resets the latch circuit 73 and 
flip-flop circuit 77 in the mixing rate control signal generating portion 
5. In this case, the mixing rate control signal MIXS takes the value "0", 
while the inverted mixing rate control signal MIXS takes the value 
"2.sup.M -1". Therefore, the waveform data W1 which is outputted as the 
second series of waveform data will be directly outputted from the 
waveform memory 1. In this case, however, the sampling data stored in the 
waveform memory 1 is standardized by the data "2.sup.M -1" which 
corresponds to the maximum value of the mixing rate control signal MIXS. 
Next, the waveform data W1 latched in the latch circuit 86 is multiplied by 
the envelope waveform signal outputted from the envelope generating 
circuit 88 in the multiplier 87. Thereafter, the digital signal indicative 
of the multiplication result of the multiplier 87 is converted into the 
analog signal in the D/A converter 91. This analog signal is supplied to 
the sound system 92. As a result, the sound system 92 will generate the 
musical tone which is obtained by applying the amplitude envelope to the 
waveform data W1. 
Due to the increase of the accumulation value of the accumulator 41, the 
value of first address signal AS1 outputted from the adder 43 becomes 
equal to that of the attack end address data outputted from the end 
address memory 47 at time T1 when the repeat start signal ST takes the 
value "0". At this time T1, the comparator 46 output the coincidence 
signal. This coincidence signal is delayed by one period of the first 
clock signal C by the delay circuit 48. Thereafter, such delayed 
coincidence signal is supplied to the reset terminal R of the accumulator 
41 via the OR circuit 42, and this signal is also supplied to the set 
terminal S of the flip-flop circuit 51. Thus, the accumulator 41 re-starts 
to output the relative address signal whose value is sequentially 
increased from "0". In addition, the flip-flop circuit 51 starts to output 
the repeat start signal ST indicative of value "1". Afterwards, the start 
address memory 44 and end address memory 47 respectively output the repeat 
start address data AD1 and repeat end address data AD3. 
This repeat start signal ST indicative of value "1" is inverted to the 
signal indicative of value "0" by the inverted 75. Then, in the mixing 
rate control signal generating portion 5, such inverted signal is supplied 
to the reset terminal R of the latch circuit 73 via the OR circuit 74, and 
such inverted signal is also supplied to the reset terminal R of the 
flip-flop circuit 77. Therefore, this inverted signal resets both of the 
latch circuit 73 and flip-flop circuit 77. Thereafter, the accumulator 
configured by the latch circuit 73 and added 72 outputs a sawtooth 
waveform signal whose value repeatedly varies between "0" and "2.sup.M -1" 
by ever half period of the repeating segment (corresponding to the period 
of AD1 to AD2 or AD2 to AD3). Due to the reset by the repeat start signal 
ST and the inverting control by the carry signal CO from the adder 72, the 
flip-flop circuit 77 supplies its output signal to the second input of 
inverter circuit 76, wherein the value of this output signal is controlled 
to be inverted by every half period of the repeating segment. More 
specifically, the output of flip-flop circuit 77 takes value "0" in the 
former half period and also takes value "1" in the latter half period of 
the repeating segment. Therefore, the mixing rate control signal MIXS 
(which is the triangular waveform signal as show in FIG. 4) outputted from 
the inverter circuit 76 repeatedly varies between "0" and "2.sup.M -1" in 
the repeating segment (corresponding to the variation period of AD1 to 
AD3) after the repeat start signal ST turns to "1". 
When the repeat start signal ST turns to "1", the accumulator 41 is reset. 
Thereafter, the accumulator 41 re-starts to perform its accumulation 
operation and the start address memory 44 generates the repeat start 
address data AD1, so that the adder 43 starts to output the first address 
signal AS1 indicative of the absolute addresses AD1 to AD3 which are used 
for reading the waveform data W2 corresponding to the repeating segment, 
and this first address signal AS1 is supplied to the first input ("1") of 
selector 45. Hereinafter, the former part of waveform data W2 is indicated 
by W2.sub.1 and the latter part thereof is indicated by W2.sub.2. In this 
state, the flip-flop circuit 64 is subjected to the set state, so that the 
selector 65 selectively outputs the first address signal AS1 to the second 
input ("0") of selector 45 as the second address signal AS2. Thus, the 
selector 45 supplies the output address signal AS0 to the waveform memory 
1 during the whole period of the first clock signal C. As a result, the 
same waveform data W2.sub.1 is read from the waveform memory 1 in both of 
the former half period (corresponding to the first series) and the latter 
half period (corresponding to the second series) of the first clock signal 
C. In addition, the addition value of the mixing rate control signal MIXS 
and inverted mixing rate control signal MIXS must indicate the value 
"2.sup.M -1", so that the waveform data W2.sub.1 will be outputted as it 
is. Thus, the sound system 92 generates the musical tone corresponding to 
the waveform data W2.sub.1. 
In the above-mentioned state, the value of first address signal AS1 becomes 
equal to the value of central address data AD2 indicative of the central 
address in the repeating segment at time T2. Accordingly, the comparator 
57 which inputs the first address signal AS1 and central address value AD2 
will supply the coincidence signal (having value "1") to the first input 
of AND circuit 63. Since the repeat start signal ST having value "1" is 
supplied to the second input of AN circuit 63, the flip-flop circuit 64 is 
reset by the coincidence signal from the comparator 57. As a result, the 
value of selecting signal SEL2 from the flip-flop circuit 64 turns to "0". 
Due to such selecting signal SEL2 supplied to the selection control 
terminal SL of the selector 65, the selector 65 selectively outputs the 
third address signal AS3 from the selector 58 as the second address signal 
AS2. 
Meanwhile, after the comparator 57 outputs the coincidence signal, the 
value of first address signal AS1 becomes larger than the central address 
value AD2, so that the selecting signal SEL3 indicates the value "0". 
Accordingly, the selector 58 outputs the signal from the subtractor 62, 
wherein this signal is the address signal (corresponding to AD1 to AD2) 
which is delayed by a half period of the repeating segment as compared to 
the first address signal AS1. Such address signal is supplied to the 
second input ("0") of selector 45 via the selectors 58 and 65 as the 
second address signal AS2. On the other hand, the first address signal AS1 
is supplied to the first input ("1") of selector 45, wherein the value of 
this first address signal AS1 varies between the central address value AD2 
and repeat end address value AD3. Therefore, the output address signal AS0 
from the selector 45 takes the value which varies from AD2 to AD3 in the 
former half period and then varies from AD1 to AD2 in the latter half 
period of the first clock signal C. Due to such output address signal AS0 
supplied to the waveform memory 1, the waveform data W2.sub.2 is read out 
as the first series of waveform data in the former half period, while the 
waveform data W2.sub.1 is read out as the second series of waveform data 
in the latter half period of the first clock signal C. 
In the above case, the value of mixing rate control signal MIXS outputted 
from the mixing rate control signal generating portion 5 is decreasing 
from "2.sup.M -1" to "0". In contrast, the inverted mixing rate control 
signal MIXS outputted from the inverter circuit 84 is increasing from "0" 
to "2.sup.M -1". In addition, the latch circuit 86 latches the output of 
adder 85 in the latter half period of the first clock signal C. Thus, 
under control of the mixing circuit consisting of the delay circuit 81, 
multipliers 82, 83, adder 85 and latch circuit 86, the mixing rate of 
waveform data W2.sub.2 as the first series of waveform data is gradually 
decreasing in the lapse of time, while another mixing rate of waveform 
data W2.sub.1 as the second series of waveform data is gradually 
increasing in the lapse of time. These waveform data W2.sub.1 and W2.sub.2 
are mixed together, so that the musical tone corresponding to the mixed 
waveform data is generated. 
Thereafter, the value of first address signal AS1 from the adder 43 becomes 
equal to the repeat end address data value AD3 at time T3. As a result, 
the comparator 46 outputs the coincidence signal again. This coincidence 
signal resets the accumulator 41 via the delay circuit 48 and OR circuit 
42. Therefore, as described before, the accumulator 41 outputs the 
relative address signal whose value is sequentially increased from "0". 
This relative address signal is added with the repeat start address data 
AD1 from the start address memory 44, so that this relative address signal 
is converted to the absolute address whose value varies from AD1 to AD3. 
Then, such absolute address signal is supplied to the first input ("1") of 
selector 45. 
Meanwhile, this first address signal AS1 is also supplied to the comparator 
57 wherein this first address signal AS1 is compared with the central 
address value AD2 from the adder 56. When the value of first address 
signal AS1 is smaller than the central address value AD2, the level of 
selecting signal SEL3 turns to "1". Therefore, the signal (AD2 to AD3) 
outputted from the adder 61 is supplied to the second input ("0") of 
selector 45 as the second address signal AS2 via the selectors 58 and 65, 
wherein this signal has the phase which is advanced by the phase 
corresponding to a half period of the repeating segment as compared to the 
phase of first address signal AS1. Thus, the selector 45 outputs the 
output address signal AS0 whose value varies from AD1 to AD2 in the former 
half period (corresponding to the first series) and then varies from AD2 
to AD3 in the latter half period (corresponding to the second series) of 
the first clock signal C. Such output address signal AS0 is supplied to 
the waveform memory 1, from which the waveform data W2.sub.1 is read as 
the first series of waveform data in the former half period and the 
waveform data W2.sub.2 is read as the second series of waveform data in 
the latter half period of the first clock signal C. 
At this time, the mixing rate control signal MIXS increases from "0" to 
"2.sup.M -1", while the inverted mixing rate control signal MIXS decreases 
from "2.sup.M -1" to "0". Under control of the foregoing mixing circuit, 
the mixing rate of the waveform data W2.sub.1 as the first series of 
waveform data is gradually increased in the lapse of time, while another 
mixing rate of the waveform data W2.sub.2 as the second series of waveform 
data is gradually decreased. Then, these waveform data W2.sub.1 and 
W2.sub.2 are mixed together. Therefore, the sound system 92 generates the 
musical tone corresponding to the mixed waveform data. 
Afterwards, the value of first address signal AS1 varies between AD2 and 
AD3 so that it becomes larger than the central address data value AD2 at 
time T4. At this time, the value of selecting signal SEL3 to be supplied 
to the selector 58 turns to "0". Thus, the address signal (AD1 to AD2) 
from the subtractor 62 is supplied to the second input ("0") of selector 
45 via the selectors 58 and 65, and simultaneously, the value of mixing 
rate control signal MIXS turns to gradually decrease from "2.sup.M -1" to 
"0". As described before, under control of the foregoing mixing circuit, 
the mixing rate of the waveform data W2.sub.2 as the first series of 
waveform data is gradually decreased in the lapse of time, while another 
mixing rate of the waveform data W2.sub.1 as the second series of waveform 
data is gradually increased in the lapse of time. Then, the sound system 
92 will generate the musical tone corresponding to the mixture of these 
waveform data W2.sub.1 and W2.sub.2. 
Thereafter, the first and second series of waveform data are mixed together 
such that mixing rate of waveform data W2.sub.1 is gradually increased but 
that of waveform data W2.sub.2 is gradually decreased. Then, the musical 
tone corresponding to the mixture of these two waveform data will be 
continuously generated. When the depressed key of the keyboard is 
released, the level of key-on signal KON turns to "0" so that the envelope 
generating circuit 88 outputs the envelope waveform signal whose value is 
attenuated. Such attenuated envelope waveform is applied to the musical 
tone to be generated. Thus, the level of the generating musical tone is 
attenuated (or muted) to zero-level. 
As described heretofore, according to the present embodiment, the waveform 
data W2 (i.e., W2.sub.1 +W2.sub.2) corresponding to the repeating segment 
is read from the waveform memory 1 based on time-sharing system as two 
series of waveform data under control of the address designating portion 
4, wherein these two series of waveform data are shifted by a half period 
of the repeating segment to each other. Then, the output circuit portion 6 
mixes these two series of waveform data together in response to the mixing 
rate cOntrol signal MIX from the mixing rate control signal generating 
portion 5. In this case, after reading out the sampling data corresponding 
to the repeat end address AD3, the sampling data corresponding to the 
repeat start address AD1 is started to be read out. At this time, the 
discontinuity due to the transfer between the readings of these two 
sampling data can be smoothed, so that the tone color variation of the 
musical tone to be generated can be smoothed. As a result, there is no 
need to process the sampling data stored in the waveform memory 1 in 
advance, so that the time and labor concerning such processing can be 
saved. In addition, even when the waveform data (i.e., sampling data) 
concerning the external tone picked up from the microphone 12 is stored as 
it is, it is possible to obtain the musical tone whose tone color can be 
varied smooth. Further, by arbitrarily setting the repeating segment by 
use of the start/end address setting unit, it is possible to obtain the 
musical tone having the great variety but whose tone color can be varied 
smooth. 
[D] MODIFIED EXAMPLES OF PRESENT EMBODIMENT 
It is possible to modify the present embodiment into several examples as 
below. 
(1) In the present embodiment, when the repeating segment is set by the 
start/end address setting unit 52, the repeat start address data AD1 and 
repeat end address data AD3 are designated by the absolute address of the 
waveform memory 1. However, it is possible to designate these data by the 
relative address of each small area within the waveform memory 1. In this 
case, the conversion process of address data in the address generating 
portion 4 is performed by the relative addresses, and then the relative 
address data to be processed is converted into the absolute address data 
of the waveform memory 1 by use of the tone color selection signal TC and 
key code KC before supplied to the waveform memory 1. 
(2) In the present embodiment, both of the repeat start address data AD1 
and repeat end address data AD3 can be arbitrarily varied. However, it is 
possible to arbitrarily vary one of these two data AD1 and AD3. 
In addition, the present embodiment sets these data AD1 and AD3 by 
inputting the numbers. However, it is possible to provide several data for 
each of these data AD1 and AD3 so that the player can arbitrarily select 
any one of these several data. 
Further, the present embodiment provides only one repeating segment. 
However, it is possible to provide two or more repeating segments as shown 
in FIG. 5. In this case the waveform data W2, W3, W4 of each repeating 
segment can be repeatedly read out. The repeating times of each waveform 
data can be fixed other than that of the lastly repeated waveform data. Of 
course, such repeating times can be arbitrarily set by the player. 
(3) The present embodiment varies the waveform of the mixing rate control 
signal MIXS as the triangular waveform. However, it is possible to vary 
the waveform of signal MIXS can be varied as the trapezoidal waveform as 
shown by the solid line in FIG. 6. In this case, the mixing rate of the 
first series of waveform data is varied by such trapezoidal waveform 
signal, while the mixing rate of the second series of waveform data is 
varied by the signal MIXS as shown by the dotted line in FIG. 6, wherein 
the phase of this signal MIXS is delayed by the phase shift between the 
first and second series as compared to that of the above trapezoidal 
waveform signal. 
In addition, the mixing rate control signal MIXS is generated by the 
calculation of the mixing rate control signal generating portion 5 in the 
present embodiment. However, it is possible to generate such signal MIXS 
by another method. For example, a memory for storing the waveform data 
concerning the foregoing triangular waveform and trapezoidal waveform is 
provided within the mixing rate control signal generating portion 5. Then, 
the reading operation of this memory is controlled by the note clock 
signal Cn, so that the signal read from this memory is outputted as the 
new mixing rate control signal MIXS. 
(4) The present embodiment describes the musical tone signal generating 
apparatus which is applied to the monophonic keyboard electronic musical 
instrument. However it is possible to apply the musical tone signal 
generating apparatus according to the present invention to the polyphonic 
musical instrument or another equipment without the keyboard but having 
the tone source unit only whose tone generation is controlled in response 
to the pitch information supplied from the external device. Further, it is 
possible to apply the present apparatus to the rhythm unit which generates 
the rhythm tones of the percussive musical instrument. 
(5) The present embodiment configures the manual control detecting portion 
3, address designating portion 4, mixing rate control signal generating 
portion 5 and output circuit portion 6 by the hardware. However, it is 
possible to perform the processings of these circuit portions by use of 
the software which will be executed by the microcomputer and the like. 
This invention may be practiced or embodied in still other ways without 
departing from the spirit or essential character thereof as described 
heretofore. Therefore, the preferred embodiment described herein is 
illustrative and not restrictive, the scope of the invention being 
indicated by the appended claims and all variations which come within the 
meaning of the claims are intended to be embraced therein.