/* (C) Guenter Geiger */ /* These filter coefficients computations are taken from http://www.harmony-central.com/Computer/Programming/Audio-EQ-Cookbook.txt written by Robert Bristow-Johnson */ #include "m_pd.h" #ifdef NT #pragma warning( disable : 4244 ) #pragma warning( disable : 4305 ) #endif #include #include "filters.h" /* ------------------- bandpass ----------------------------*/ static t_class *bandpass_class; void bandpass_bang(t_rbjfilter *x) { t_atom at[5]; t_float omega = e_omega(x->x_freq,x->x_rate); t_float alpha = e_alpha(x->x_bw* 0.01,omega); t_float b1 = 0.; t_float b0 = alpha; t_float b2 = -alpha; t_float a0 = 1 + alpha; t_float a1 = -2.*cos(omega); t_float a2 = 1 - alpha; /* post("bang %f %f %f",x->x_freq, x->x_gain, x->x_bw); */ if (!check_stability(-a1/a0,-a2/a0,b0/a0,b1/a0,b2/a0)) { post("bandpass: filter unstable -> resetting"); a0=1.;a1=0.;a2=0.; b0=1.;b1=0.;b2=0.; } SETFLOAT(at,-a1/a0); SETFLOAT(at+1,-a2/a0); SETFLOAT(at+2,b0/a0); SETFLOAT(at+3,b1/a0); SETFLOAT(at+4,b2/a0); outlet_list(x->x_obj.ob_outlet,&s_list,5,at); } void bandpass_float(t_rbjfilter *x,t_floatarg f) { x->x_freq = f; bandpass_bang(x); } static void *bandpass_new(t_floatarg f,t_floatarg bw) { t_rbjfilter *x = (t_rbjfilter *)pd_new(bandpass_class); x->x_rate = 44100.0; outlet_new(&x->x_obj,&s_float); /* floatinlet_new(&x->x_obj, &x->x_gain); */ floatinlet_new(&x->x_obj, &x->x_bw); if (f > 0.) x->x_freq = f; if (bw > 0.) x->x_bw = bw; return (x); } void bandpass_setup(void) { bandpass_class = class_new(gensym("bandpass"), (t_newmethod)bandpass_new, 0, sizeof(t_rbjfilter), 0,A_DEFFLOAT,A_DEFFLOAT,0); class_addbang(bandpass_class,bandpass_bang); class_addfloat(bandpass_class,bandpass_float); } /* (C) Guenter Geiger */ /* These filter coefficients computations are taken from http://www.harmony-central.com/Computer/Programming/Audio-EQ-Cookbook.txt written by Robert Bristow-Johnson */ #include "m_pd.h" #ifdef NT #pragma warning( disable : 4244 ) #pragma warning( disable : 4305 ) #endif #include #include "filters.h" /* ------------------- bandpass ----------------------------*/ static t_class *bandpass_class; void bandpass_bang(t_rbjfilter *x) { t_atom at[5]; t_float omega = e_omega(x->x_freq,x->x_rate); t_float alpha = e_alpha(x->x_bw* 0.01,omega); t_float b1 = 0.; t_float b0 = alpha; t_float b2 = -alpha; t_float a0 = 1 + alpha; t_float a1 = -2.*cos(omega); t_float a2 = 1 - alpha; /* post("bang %f %f %f",x->x_freq, x->x_gain, x->x_bw); */ if (!check_stability(-a1/a0,-a2/a0,b0/a0,b1/a0,b2/a0)) { post("bandpass: filter unstable -> resetting"); a0=1.;a1=0.;a2=0.; b0=1.;b1=0.;b2=0.; } SETFLOAT(at,-a1/a0); SETFLOAT(at+1,-a2/a0); SETFLOAT(at+2,b0/a0); SETFLOAT(at+3,b1/a0); SETFLOAT(at+4,b2/a0); outlet_list(x->x_obj.ob_outlet,&s_list,5,at); } void bandpass_float(t_rbjfilter *x,t_floatarg f) { x->x_freq = f; bandpass_bang(x); } static void *bandpass_new(t_floatarg f,t_floatarg bw) { t_rbjfilter *x = (t_rbjfilter *)pd_new(bandpass_class); x->x_rate = 44100.0; outlet_new(&x->x_obj,&s_float); /* floatinlet_new(&x->x_obj, &x->x_gain); */ floatinlet_new(&x->x_obj, &x->x_bw); if (f > 0.) x->x_freq = f; if (bw > 0.) x->x_bw = bw; return (x); } void bandpass_setup(void) { bandpass_class = class_new(gensym("bandpass"), (t_newmethod)bandpass_new, 0, sizeof(t_rbjfilter), 0,A_DEFFLOAT,A_DEFFLOAT,0); class_addbang(bandpass_class,bandpass_bang); class_addfloat(bandpass_class,bandpass_float); }