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#N canvas 1356 280 739 524 10;
#X declare -lib cyclone;
#X text 15 35 Sample-and-hold;
#X obj 109 405 cycle~;
#X obj 109 377 *~ 1000;
#X obj 109 433 *~ 0.2;
#X floatatom 109 208 0 0 0 0 - - -;
#X obj 109 241 phasor~ 20;
#X floatatom 323 206 0 0 0 0 - - -;
#X floatatom 122 270 0 0 0 0 - - -;
#X obj 109 468 dac~;
#X obj 323 239 phasor~ 11.33;
#X text 282 312 Optional argument sets trigger value for control input
(default 0) \; you need a trigger above 0 to work with phasor~;
#X text 13 171 You've heard it before: the classic arpeggiator \, made
with two phasor~ objects;
#X text 207 290 control signal;
#X text 29 294 input signal;
#X text 161 377 sah~ output used as the frequency of an oscillator
;
#X text 161 271 set trigger;
#X obj 436 104 import cyclone;
#X obj 109 310 sah~ 0.01;
#X text 16 60 The sah~ object accepts two signals. The left signal
is the "input" and the right signal is the "control." When the control
makes a transition from being at or below the trigger value to being
above the trigger value \, the input is sampled and its current value
is output until another control transition occurs and the input is
sampled again. The default threshold value is 0 \, but can be specified
via a float in the left inlet or as an argument to sah~.;
#X connect 1 0 3 0;
#X connect 2 0 1 0;
#X connect 3 0 8 0;
#X connect 3 0 8 1;
#X connect 4 0 5 0;
#X connect 5 0 17 0;
#X connect 6 0 9 0;
#X connect 7 0 17 0;
#X connect 9 0 17 1;
#X connect 17 0 2 0;
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