ref: 8fa6f230775bf0c036441bf7d5d941e2312709dc
dir: /LEAF/Src/leaf-electrical.c/
/* * leaf-electrical.c * * Created on: Sep 25, 2019 * Author: jeffsnyder */ #if _WIN32 || _WIN64 #include "..\Inc\leaf-electrical.h" #include "..\leaf.h" #else #include "../Inc/leaf-electrical.h" #include "../leaf.h" #endif //============================================================================== static float get_port_resistance_for_resistor(tWDF* const r); static float get_port_resistance_for_capacitor(tWDF* const r); static float get_port_resistance_for_inductor(tWDF* const r); static float get_port_resistance_for_resistive(tWDF* const r); static float get_port_resistance_for_inverter(tWDF* const r); static float get_port_resistance_for_series(tWDF* const r); static float get_port_resistance_for_parallel(tWDF* const r); static float get_port_resistance_for_root(tWDF* const r); static void set_incident_wave_for_leaf(tWDF* const r, float incident_wave, float input); static void set_incident_wave_for_leaf_inverted(tWDF* const r, float incident_wave, float input); static void set_incident_wave_for_inverter(tWDF* const r, float incident_wave, float input); static void set_incident_wave_for_series(tWDF* const r, float incident_wave, float input); static void set_incident_wave_for_parallel(tWDF* const r, float incident_wave, float input); static float get_reflected_wave_for_resistor(tWDF* const r, float input); static float get_reflected_wave_for_capacitor(tWDF* const r, float input); static float get_reflected_wave_for_resistive(tWDF* const r, float input); static float get_reflected_wave_for_inverter(tWDF* const r, float input); static float get_reflected_wave_for_series(tWDF* const r, float input); static float get_reflected_wave_for_parallel(tWDF* const r, float input); static float get_reflected_wave_for_ideal(tWDF* const n, float input, float incident_wave); static float get_reflected_wave_for_diode(tWDF* const n, float input, float incident_wave); static float get_reflected_wave_for_diode_pair(tWDF* const n, float input, float incident_wave); static void wdf_init(tWDF* const wdf, WDFComponentType type, float value, tWDF* const rL, tWDF* const rR) { _tWDF* r = *wdf; r->type = type; r->child_left = rL; r->child_right = rR; r->incident_wave_up = 0.0f; r->incident_wave_left = 0.0f; r->incident_wave_right = 0.0f; r->reflected_wave_up = 0.0f; r->reflected_wave_left = 0.0f; r->reflected_wave_right = 0.0f; r->sample_rate = leaf.sampleRate; r->value = value; tWDF* child; if (r->child_left != NULL) child = r->child_left; else child = r->child_right; if (r->type == Resistor) { r->port_resistance_up = r->value; r->port_conductance_up = 1.0f / r->value; r->get_port_resistance = &get_port_resistance_for_resistor; r->get_reflected_wave_up = &get_reflected_wave_for_resistor; r->set_incident_wave = &set_incident_wave_for_leaf; } else if (r->type == Capacitor) { r->port_conductance_up = r->sample_rate * 2.0f * r->value; r->port_resistance_up = 1.0f / r->port_conductance_up; //based on trapezoidal discretization r->get_port_resistance = &get_port_resistance_for_capacitor; r->get_reflected_wave_up = &get_reflected_wave_for_capacitor; r->set_incident_wave = &set_incident_wave_for_leaf; } else if (r->type == Inductor) { r->port_resistance_up = r->sample_rate * 2.0f * r->value; //based on trapezoidal discretization r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_port_resistance = &get_port_resistance_for_inductor; r->get_reflected_wave_up = &get_reflected_wave_for_capacitor; // same as capacitor r->set_incident_wave = &set_incident_wave_for_leaf_inverted; } else if (r->type == ResistiveSource) { r->port_resistance_up = r->value; r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_port_resistance = &get_port_resistance_for_resistive; r->get_reflected_wave_up = &get_reflected_wave_for_resistive; r->set_incident_wave = &set_incident_wave_for_leaf; } else if (r->type == Inverter) { r->port_resistance_up = tWDF_getPortResistance(r->child_left); r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_port_resistance = &get_port_resistance_for_inverter; r->get_reflected_wave_up = &get_reflected_wave_for_inverter; r->set_incident_wave = &set_incident_wave_for_inverter; } else if (r->type == SeriesAdaptor) { r->port_resistance_left = tWDF_getPortResistance(r->child_left); r->port_resistance_right = tWDF_getPortResistance(r->child_right); r->port_resistance_up = r->port_resistance_left + r->port_resistance_right; r->port_conductance_up = 1.0f / r->port_resistance_up; r->port_conductance_left = 1.0f / r->port_resistance_left; r->port_conductance_right = 1.0f / r->port_resistance_right; r->gamma_zero = 1.0f / (r->port_resistance_right + r->port_resistance_left); r->get_port_resistance = &get_port_resistance_for_series; r->get_reflected_wave_up = &get_reflected_wave_for_series; r->set_incident_wave = &set_incident_wave_for_series; } else if (r->type == ParallelAdaptor) { r->port_resistance_left = tWDF_getPortResistance(r->child_left); r->port_resistance_right = tWDF_getPortResistance(r->child_right); r->port_resistance_up = (r->port_resistance_left * r->port_resistance_right) / (r->port_resistance_left + r->port_resistance_right); r->port_conductance_up = 1.0f / r->port_resistance_up; r->port_conductance_left = 1.0f / r->port_resistance_left; r->port_conductance_right = 1.0f / r->port_resistance_right; r->gamma_zero = 1.0f / (r->port_resistance_right + r->port_resistance_left); r->get_port_resistance = &get_port_resistance_for_parallel; r->get_reflected_wave_up = &get_reflected_wave_for_parallel; r->set_incident_wave = &set_incident_wave_for_parallel; } else if (r->type == IdealSource) { r->port_resistance_up = tWDF_getPortResistance(child); r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_reflected_wave_down = &get_reflected_wave_for_ideal; r->get_port_resistance = &get_port_resistance_for_root; } else if (r->type == Diode) { r->port_resistance_up = tWDF_getPortResistance(child); r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_reflected_wave_down = &get_reflected_wave_for_diode; r->get_port_resistance = &get_port_resistance_for_root; } else if (r->type == DiodePair) { r->port_resistance_up = tWDF_getPortResistance(child); r->port_conductance_up = 1.0f / r->port_resistance_up; r->get_reflected_wave_down = &get_reflected_wave_for_diode_pair; r->get_port_resistance = &get_port_resistance_for_root; } } //WDF void tWDF_init(tWDF* const wdf, WDFComponentType type, float value, tWDF* const rL, tWDF* const rR) { *wdf = (_tWDF*) leaf_alloc(sizeof(_tWDF)); wdf_init(wdf, type, value, rL, rR); } void tWDF_free(tWDF* const wdf) { _tWDF* r = *wdf; leaf_free(r); } void tWDF_initToPool (tWDF* const wdf, WDFComponentType type, float value, tWDF* const rL, tWDF* const rR, tMempool* const mp) { _tMempool* m = *mp; *wdf = (_tWDF*) mpool_alloc(sizeof(_tWDF), &m->pool); wdf_init(wdf, type, value, rL, rR); } void tWDF_freeFromPool (tWDF* const wdf, tMempool* const mp) { _tMempool* m = *mp; _tWDF* r = *wdf; mpool_free(r, &m->pool); } float tWDF_tick(tWDF* const wdf, float sample, tWDF* const outputPoint, uint8_t paramsChanged) { _tWDF* r = *wdf; tWDF* child; if (r->child_left != NULL) child = r->child_left; else child = r->child_right; //step 0 : update port resistances if something changed if (paramsChanged) tWDF_getPortResistance(wdf); //step 1 : set inputs to what they should be float input = sample; //step 2 : scan the waves up the tree r->incident_wave_up = tWDF_getReflectedWaveUp(child, input); //step 3 : do root scattering computation r->reflected_wave_up = tWDF_getReflectedWaveDown(wdf, input, r->incident_wave_up); //step 4 : propogate waves down the tree tWDF_setIncidentWave(child, r->reflected_wave_up, input); //step 5 : grab whatever voltages or currents we want as outputs return tWDF_getVoltage(outputPoint); } void tWDF_setValue(tWDF* const wdf, float value) { _tWDF* r = *wdf; r->value = value; } void tWDF_setSampleRate(tWDF* const wdf, float sample_rate) { _tWDF* r = *wdf; r->sample_rate = sample_rate; } uint8_t tWDF_isLeaf(tWDF* const wdf) { _tWDF* r = *wdf; if (r->child_left == NULL && r->child_right == NULL) return 1; return 0; } float tWDF_getPortResistance(tWDF* const wdf) { _tWDF* r = *wdf; return r->get_port_resistance(wdf); } void tWDF_setIncidentWave(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->set_incident_wave(wdf, incident_wave, input); } float tWDF_getReflectedWaveUp(tWDF* const wdf, float input) { _tWDF* r = *wdf; return r->get_reflected_wave_up(wdf, input); } float tWDF_getReflectedWaveDown(tWDF* const wdf, float input, float incident_wave) { _tWDF* r = *wdf; return r->get_reflected_wave_down(wdf, input, incident_wave); } float tWDF_getVoltage(tWDF* const wdf) { _tWDF* r = *wdf; return ((r->incident_wave_up * 0.5f) + (r->reflected_wave_up * 0.5f)); } float tWDF_getCurrent(tWDF* const wdf) { _tWDF* r = *wdf; return (((r->incident_wave_up * 0.5f) - (r->reflected_wave_up * 0.5f)) * r->port_conductance_up); } //============ Static Functions to be Pointed To ==================== //=================================================================== //============ Get and Calculate Port Resistances =================== static float get_port_resistance_for_resistor(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_up = r->value; r->port_conductance_up = 1.0f / r->value; return r->port_resistance_up; } static float get_port_resistance_for_capacitor(tWDF* const wdf) { _tWDF* r = *wdf; r->port_conductance_up = r->sample_rate * 2.0f * r->value; //based on trapezoidal discretization r->port_resistance_up = (1.0f / r->port_conductance_up); return r->port_resistance_up; } static float get_port_resistance_for_inductor(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_up = r->sample_rate * 2.0f * r->value; //based on trapezoidal discretization r->port_conductance_up = (1.0f / r->port_resistance_up); return r->port_resistance_up; } static float get_port_resistance_for_resistive(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_up = r->value; r->port_conductance_up = 1.0f / r->port_resistance_up; return r->port_resistance_up; } static float get_port_resistance_for_inverter(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_up = tWDF_getPortResistance(r->child_left); r->port_conductance_up = 1.0f / r->port_resistance_up; return r->port_resistance_up; } static float get_port_resistance_for_series(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_left = tWDF_getPortResistance(r->child_left); r->port_resistance_right = tWDF_getPortResistance(r->child_right); r->port_resistance_up = r->port_resistance_left + r->port_resistance_right; r->port_conductance_up = 1.0f / r->port_resistance_up; r->port_conductance_left = 1.0f / r->port_resistance_left; r->port_conductance_right = 1.0f / r->port_resistance_right; r->gamma_zero = 1.0f / (r->port_resistance_right + r->port_resistance_left); return r->port_resistance_up; } static float get_port_resistance_for_parallel(tWDF* const wdf) { _tWDF* r = *wdf; r->port_resistance_left = tWDF_getPortResistance(r->child_left); r->port_resistance_right = tWDF_getPortResistance(r->child_right); r->port_resistance_up = (r->port_resistance_left * r->port_resistance_right) / (r->port_resistance_left + r->port_resistance_right); r->port_conductance_up = 1.0f / r->port_resistance_up; r->port_conductance_left = 1.0f / r->port_resistance_left; r->port_conductance_right = 1.0f / r->port_resistance_right; r->gamma_zero = 1.0f / (r->port_conductance_right + r->port_conductance_left); return r->port_resistance_up; } static float get_port_resistance_for_root(tWDF* const wdf) { _tWDF* r = *wdf; tWDF* child; if (r->child_left != NULL) child = r->child_left; else child = r->child_right; r->port_resistance_up = tWDF_getPortResistance(child); r->port_conductance_up = 1.0f / r->port_resistance_up; return r->port_resistance_up; } //=================================================================== //================ Set Incident Waves =============================== static void set_incident_wave_for_leaf(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->incident_wave_up = incident_wave; } static void set_incident_wave_for_leaf_inverted(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->incident_wave_up = -1.0f * incident_wave; } static void set_incident_wave_for_inverter(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->incident_wave_up = incident_wave; tWDF_setIncidentWave(r->child_left, -1.0f * incident_wave, input); } static void set_incident_wave_for_series(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->incident_wave_up = incident_wave; float gamma_left = r->port_resistance_left * r->gamma_zero; float gamma_right = r->port_resistance_right * r->gamma_zero; float left_wave = tWDF_getReflectedWaveUp(r->child_left, input); float right_wave = tWDF_getReflectedWaveUp(r->child_right, input); // downPorts[0]->b = yl * ( downPorts[0]->a * ((1.0 / yl) - 1) - downPorts[1]->a - descendingWave ); // downPorts[1]->b = yr * ( downPorts[1]->a * ((1.0 / yr) - 1) - downPorts[0]->a - descendingWave ); tWDF_setIncidentWave(r->child_left, (-1.0f * gamma_left * incident_wave) + (gamma_right * left_wave) - (gamma_left * right_wave), input); tWDF_setIncidentWave(r->child_right, (-1.0f * gamma_right * incident_wave) + (gamma_left * right_wave) - (gamma_right * left_wave), input); // From rt-wdf // tWDF_setIncidentWave(r->child_left, gamma_left * (left_wave * ((1.0f / gamma_left) - 1.0f) - right_wave - incident_wave)); // tWDF_setIncidentWave(r->child_right, gamma_right * (right_wave * ((1.0f / gamma_right) - 1.0f) - left_wave - incident_wave)); } static void set_incident_wave_for_parallel(tWDF* const wdf, float incident_wave, float input) { _tWDF* r = *wdf; r->incident_wave_up = incident_wave; float gamma_left = r->port_conductance_left * r->gamma_zero; float gamma_right = r->port_conductance_right * r->gamma_zero; float left_wave = tWDF_getReflectedWaveUp(r->child_left, input); float right_wave = tWDF_getReflectedWaveUp(r->child_right, input); // downPorts[0]->b = ( ( dl - 1 ) * downPorts[0]->a + dr * downPorts[1]->a + du * descendingWave ); // downPorts[1]->b = ( dl * downPorts[0]->a + ( dr - 1 ) * downPorts[1]->a + du * descendingWave ); tWDF_setIncidentWave(r->child_left, (gamma_left - 1.0f) * left_wave + gamma_right * right_wave + incident_wave, input); tWDF_setIncidentWave(r->child_right, gamma_left * left_wave + (gamma_right - 1.0f) * right_wave + incident_wave, input); } //=================================================================== //================ Get Reflected Waves ============================== static float get_reflected_wave_for_resistor(tWDF* const wdf, float input) { _tWDF* r = *wdf; r->reflected_wave_up = 0.0f; return r->reflected_wave_up; } static float get_reflected_wave_for_capacitor(tWDF* const wdf, float input) { _tWDF* r = *wdf; r->reflected_wave_up = r->incident_wave_up; return r->reflected_wave_up; } static float get_reflected_wave_for_resistive(tWDF* const wdf, float input) { _tWDF* r = *wdf; r->reflected_wave_up = input; return r->reflected_wave_up; } static float get_reflected_wave_for_inverter(tWDF* const wdf, float input) { _tWDF* r = *wdf; r->reflected_wave_up = -1.0f * tWDF_getReflectedWaveUp(r->child_left, input); return r->reflected_wave_up; } static float get_reflected_wave_for_series(tWDF* const wdf, float input) { _tWDF* r = *wdf; //-( downPorts[0]->a + downPorts[1]->a ); r->reflected_wave_up = (-1.0f * (tWDF_getReflectedWaveUp(r->child_left, input) + tWDF_getReflectedWaveUp(r->child_right, input))); return r->reflected_wave_up; } static float get_reflected_wave_for_parallel(tWDF* const wdf, float input) { _tWDF* r = *wdf; float gamma_left = r->port_conductance_left * r->gamma_zero; float gamma_right = r->port_conductance_right * r->gamma_zero; //return ( dl * downPorts[0]->a + dr * downPorts[1]->a ); r->reflected_wave_up = (gamma_left * tWDF_getReflectedWaveUp(r->child_left, input) + gamma_right * tWDF_getReflectedWaveUp(r->child_right, input)); return r->reflected_wave_up; } static float get_reflected_wave_for_ideal(tWDF* const wdf, float input, float incident_wave) { return (2.0f * input) - incident_wave; } #define l2A 0.1640425613334452f #define l2B -1.098865286222744f #define l2Y 3.148297929334117f #define l2K -2.213475204444817f static float log2Approximation(float x) { return (l2A * x*x*x) + (l2B * x*x) + (l2Y * x) + l2K; } #define wX1 -3.684303659906469f #define wX2 1.972967391708859f #define wA 9.451797158780131e-3f #define wB 0.1126446405111627f #define wY 0.4451353886588814f #define wK 0.5836596684310648f static float wrightOmega3(float x) { if (x <= wX1) { return 0; } else if (x < wX2) { return (wA * x*x*x) + (wB * x*x) + (wY * x) + wK; } else { return x - logf(x); } } static float wrightOmegaApproximation(float x) { float w3 = wrightOmega3(x); return w3 - ((w3 - expf(x - w3)) / (w3 + 1.0f)); } static float lambertW(float a, float r, float I, float iVT) { return wrightOmegaApproximation(((a + r*I) * iVT) + log((r * I) * iVT)); } #define Is_DIODE 2.52e-9f #define VT_DIODE 0.02585f static float get_reflected_wave_for_diode(tWDF* const wdf, float input, float incident_wave) { _tWDF* n = *wdf; float a = incident_wave; float r = n->port_resistance_up; return a + 2.0f*r*Is_DIODE - 2.0f*VT_DIODE*lambertW(a, r, Is_DIODE, 1.0f/VT_DIODE); } static float get_reflected_wave_for_diode_pair(tWDF* const wdf, float input, float incident_wave) { _tWDF* n = *wdf; float a = incident_wave; float sgn = 0.0f; if (a > 0.0f) sgn = 1.0f; else if (a < 0.0f) sgn = -1.0f; float r = n->port_resistance_up; return a + 2 * sgn * (r*Is_DIODE - VT_DIODE*lambertW(sgn*a, r, Is_DIODE, 1.0f/VT_DIODE)); }