File: weightonset-help.pd

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pd-ekext 0.1.1-3
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file content (261 lines) | stat: -rw-r--r-- 7,839 bytes parent folder | download | duplicates (3)
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#N canvas 31 64 901 594 10;
#N canvas 1901 230 450 300 hasc 0;
#X obj 65 62 inlet~;
#X obj 196 184 block~ 1024;
#X obj 55 106 rfft~;
#X obj 56 150 hasc~;
#X obj 56 188 outlet;
#X obj 179 60 inlet;
#X text 153 42 threshold (0-10+);
#X text 43 -1 ...get a "highest apparent spectral component" value
from the FFT;
#X connect 0 0 2 0;
#X connect 2 0 3 0;
#X connect 2 1 3 1;
#X connect 3 0 4 0;
#X connect 5 0 3 2;
#X restore 44 446 pd hasc;
#X obj 128 374 bonk~;
#N canvas 0 0 450 300 (subpatch) 0;
#X array \$0-input 106595 float 0;
#X coords 0 1 106594 -1 200 51 1;
#X restore 287 337 graph;
#X obj 128 398 t b b;
#X obj 81 534 f;
#X floatatom 96 515 5 0 0 0 - - -;
#X floatatom 168 376 5 0 99 0 - - -;
#X obj 81 554 print end-value;
#X obj 43 352 tabplay~ \$0-input;
#X floatatom 75 382 5 0 100 0 - - -;
#X floatatom 75 424 5 0 0 0 - - -;
#X obj 75 402 * 0.1;
#N canvas 0 0 450 300 tw 0;
#X obj 274 70 inlet;
#X msg 274 91 0;
#X obj 191 158 cup;
#X obj 110 55 inlet;
#X obj 110 80 t f b;
#X obj 115 207 tabwrite \$0-hasc;
#X obj 301 158 cup;
#X obj 220 55 inlet;
#X obj 220 80 t f b;
#X obj 225 207 tabwrite \$0-weightonset;
#X connect 0 0 1 0;
#X connect 1 0 2 0;
#X connect 1 0 6 0;
#X connect 2 0 5 1;
#X connect 3 0 4 0;
#X connect 4 0 5 0;
#X connect 4 1 2 0;
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#X array \$0-hasc 1 float 3;
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#X coords 0 511 1 -1 200 51 1;
#X restore 287 408 graph;
#N canvas 0 0 450 300 adapt 0;
#X obj 128 44 inlet;
#X obj 127 74 / 100;
#X obj 129 108 t b f;
#X msg 126 139 1;
#X obj 132 170 -;
#X obj 134 205 outlet;
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#X connect 2 1 4 1;
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#X restore 168 395 pd adapt;
#X floatatom 168 429 5 0 0 1 influence - -;
#X obj 168 336 loadbang;
#X obj 88 304 bng 15 250 50 0 empty empty load 17 7 0 10 -262144 -1
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#N canvas 211 176 325 300 loadfile 0;
#X obj 44 28 openpanel;
#X obj 44 47 t a b;
#X obj 44 90 pack s s;
#X msg 44 109 read -resize \$1 \$2;
#X obj 44 128 soundfiler;
#X obj 71 66 symbol \$0-input;
#X floatatom 44 186 0 0 0 0 - - -;
#X obj 44 166 i;
#X msg 44 206 resize \$1;
#X obj 44 226 s \$0-hasc;
#X obj 44 147 / 1024;
#X obj 44 5 inlet;
#X obj 113 227 s \$0-weightonset;
#X obj 243 27 loadbang;
#X msg 119 27 examples/stink.wav;
#X connect 0 0 1 0;
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#X connect 1 1 5 0;
#X connect 2 0 3 0;
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#X connect 4 0 10 0;
#X connect 5 0 2 1;
#X connect 6 0 8 0;
#X connect 7 0 6 0;
#X connect 8 0 9 0;
#X connect 8 0 12 0;
#X connect 10 0 7 0;
#X connect 11 0 0 0;
#X connect 13 0 14 0;
#X connect 14 0 1 0;
#X restore 88 323 pd loadfile;
#X obj 43 304 bng 12 250 50 0 empty empty play 15 6 0 10 -262144 -1
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#X obj 43 319 t b b;
#N canvas 0 0 450 300 (subpatch) 0;
#X array \$0-weightonset 1 float 3;
#A 0 0;
#X coords 0 511 1 -1 200 51 1;
#X restore 287 478 graph;
#X obj 116 435 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-257985 -1;
#X text 56 49 The second value is multipled by the value in the second
inlet (range 0-1) and added to the first value. Then \, the divider
value (in order to work out the weighted average) is also multiplied
by this value \, and added to it.;
#X text 46 8 This object makes a moving average with successively less
important values. The calculation initiates when the object is banged
\, and the first value is the most influential.;
#X msg 65 472 1;
#X obj 130 473 bng 15 250 50 0 empty empty empty 17 7 0 10 -262144
-1 -1;
#X obj 195 528 print data;
#X text 78 161 When the object is banged the right outlet sends a list
of all the values that influenced the result since the last bang \,
up to a limit of 1024 values.;
#X obj 477 73 weightonset;
#X text 476 58 V;
#X text 476 54 |;
#X text 476 44 |;
#X text 476 34 |;
#X text 452 20 floats in;
#X text 506 58 V;
#X text 506 54 |;
#X text 506 44 |;
#X text 685 338 ^;
#X text 684 342 |;
#X text 684 351 |;
#X text 738 338 ^;
#X text 737 342 |;
#X text 737 351 |;
#X text 801 338 ^;
#X text 800 342 |;
#X text 800 351 |;
#X text 671 377 of successive inputs;
#X text 475 89 |;
#X text 475 99 |;
#X text 475 109 |;
#X text 475 119 V;
#X text 452 141 influenced;
#X text 464 130 onset-;
#X text 465 153 value;
#X text 538 89 |;
#X text 538 99 |;
#X text 538 109 |;
#X text 538 119 V;
#X text 531 132 data dump;
#X text 537 143 on bang;
#X msg 49 382 5;
#X text 212 439 factor;
#X text 202 415 successive;
#X text 64 101 The influence of successive values is lessened by the
inverse of the factor on the right inlet. So \, a value of 0.2 in the
second inlet means that the second value after the bang is 20% as influential
as the first \, and the third value is 20% of 20% (4%) as influential
as the first.;
#X floatatom 195 465 5 0 10 1 attack - -;
#X text 509 200 influence factor = 0 : 1st float output only;
#X text 510 188 attack length = 0 \,;
#X text 535 166 EXAMPLES:;
#X text 520 226 attack length = 0 \,;
#X text 519 238 influence factor = 1: successive values are;
#X text 232 475 phase;
#X text 232 489 0-100;
#X text 508 252 equally influential to the total \, but the list;
#X text 492 31 successive influence factor (0-1);
#X text 538 58 V;
#X text 538 54 |;
#X text 514 265 grows longer as the numbers are added. Therefore;
#X text 506 278 the output responds less and less to input values.
;
#X text 513 291 This is an accumulating average between bangs.;
#X text 511 313 attack length = 0 \,;
#X text 634 366 (w) = weightings (influence values);
#X text 509 393 the output is onset-weighted e.g. the most influential
values are at the start of the series.;
#X text 699 462 ^;
#X text 698 466 |;
#X text 698 475 |;
#X text 769 462 ^;
#X text 768 466 |;
#X text 768 475 |;
#X text 832 462 ^;
#X text 831 466 |;
#X text 831 475 |;
#X text 680 501 of successive inputs;
#X text 656 490 (w) = weightings (influence values);
#X text 517 437 attack length = 3 \,;
#X text 509 327 influence factor = 0.5: v1 w 1 \, v2 w 0.5 \, v3 w
0.25 \, v4 w 0.125;
#X text 86 200 If the attack phase is greater than 0 \, the values
become successively more influential to the weighted average \, until
the number of values is equal to the attack+1. The next value after
the attack phase is the most influential \, then the influence factor
kicks in and successive values become less influential.;
#X text 557 71 creation args: influence factor \, attack;
#X obj 96 495 weightonset 0.8 0;
#X obj 10 381 dac~;
#X msg 168 356 80;
#X text 513 451 influence factor = 0.5: v1 w 0.125 \, v2 w 0.25 \,
v3 w 0.5 \, v4 w 1 \, v5 w 0.5 \, v6 w 0.25...;
#X text 525 43 attack phase (0-100+);
#X obj 664 183 weightonset 0 0;
#X obj 666 222 weightonset 1 0;
#X obj 674 312 weightonset 0.5 0;
#X obj 676 434 weightonset 0.5 3;
#X text 509 517 the output is onset-weighted e.g. the most influential
values are at the start of the series \, after the attack phase in
which the values become successively more influential.;
#X text 99 269 The weightings of values during the attack phase is
the reverse of successive weightings after the attack:;
#X text 226 294 weighting = influence pow(attack - index);
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