sp-filtergraph~.pd

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#X text 166 7 filter-graph1 -- generate sinusoids to test a filter
;
#X text 168 23 arg 1: number of steps - arg2: frequency range;
#X text 40 53 This \, together with its companion filter-graph2 \,
measure a filter's frequency and phase response. Here we count from
0 to n-1 (where n is the table size) and output the index and a complex
sinusoid at each frequency to test.;
#X text 222 192 fudge to estimate settling time;
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#X text 257 102 test sinusoid:;
#X text 272 116 cos;
#X text 325 115 sin;
#X text 397 97 output of filter;
#X text 398 113 we're testing;
#X text 31 103 index and time to next step;
#X text 39 82 ----- from filter-graph1's 3 outlets: -------;
#X text 117 193 low-pass filters;
#X text 118 177 cutoff freq. for;
#X obj 464 163 t b;
#X text 583 184 clear filters;
#X text 582 198 to start;
#X text 31 3 filter-graph2: measures frequency and phase response of
a filter \, which should be driven by a "filter-graph1" object. We
need the three outputs of filter-graph1 \, plus the filter output.
;
#X text 438 55 1: table name for frequency response;
#X text 518 39 creation arguments:;
#X text 438 71 2 (optional): table name for phase response;
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#X text 68 10 3-pole \, 3-zero butterworth lp/hp/shelving filter. Args:
lp freq \, hp freq \, normalize-hi. Inlets: input signal \, lo freq
\, hi freq \, hi norm \, reset.;
#X text 70 75 For high-pass: set LP freq =0 and hi/lo to 1;
#X text 70 56 For low-pass: set HP freq >= SR/2 and hi/lo to 0;
#X text 69 92 Shelving: HP and LP specify shelving band. Gain difference
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#X text 59 30 characteristic frequency \, 0(DC) to 1(Nyquist);
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#X text 119 4 3-pole (or zero) Butterworth filter coefficient calculator
;
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#X text 211 138 conjugate pair of pole/zero locations:;
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#X text 270 282 real-valued one \, theta=0;
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;
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#X text 68 10 3-pole \, 3-zero butterworth lp/hp/shelving filter. Args:
lp freq \, hp freq \, normalize-hi. Inlets: input signal \, lo freq
\, hi freq \, hi norm \, reset.;
#X text 70 75 For high-pass: set LP freq =0 and hi/lo to 1;
#X text 70 56 For low-pass: set HP freq >= SR/2 and hi/lo to 0;
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#X text 59 30 characteristic frequency \, 0(DC) to 1(Nyquist);
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#X text 119 4 3-pole (or zero) Butterworth filter coefficient calculator
;
#X text 145 109 "theta" in units of pi/2;
#X text 211 138 conjugate pair of pole/zero locations:;
#X text 197 155 real part: (1-r*r)/(1+r*r-2rcos(th));
#X text 245 226 imaginary part: 2rsin(th)/(...);
#X text 270 282 real-valued one \, theta=0;
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#X text 119 4 3-pole (or zero) Butterworth filter coefficient calculator
;
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#X text 211 138 conjugate pair of pole/zero locations:;
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