#include "calibration.h" #include #include #include #include #include "unit.h" #include using namespace std; Calibration::Calibration() { // Create vectors for measurements measurements[Measurement::Port1Open].datapoints = vector(); measurements[Measurement::Port1Short].datapoints = vector(); measurements[Measurement::Port1Load].datapoints = vector(); measurements[Measurement::Port2Open].datapoints = vector(); measurements[Measurement::Port2Short].datapoints = vector(); measurements[Measurement::Port2Load].datapoints = vector(); measurements[Measurement::Isolation].datapoints = vector(); measurements[Measurement::Through].datapoints = vector(); measurements[Measurement::Line].datapoints = vector(); type = Type::None; } void Calibration::clearMeasurements() { qDebug() << "Clearing all calibration measurements..."; for(auto m : measurements) { clearMeasurement(m.first); } } void Calibration::clearMeasurement(Calibration::Measurement type) { measurements[type].datapoints.clear(); measurements[type].timestamp = QDateTime(); qDebug() << "Deleted" << MeasurementToString(type) << "measurement"; } void Calibration::addMeasurement(Calibration::Measurement type, Protocol::Datapoint &d) { measurements[type].datapoints.push_back(d); measurements[type].timestamp = QDateTime::currentDateTime(); } bool Calibration::calculationPossible(Calibration::Type type) { if(type == Type::None) { // always possible to reset to None return true; } qDebug() << "Checking if" << TypeToString(type) << "calibration is possible..."; auto ret = SanityCheckSamples(Measurements(type, false)); if(ret) { qDebug() << "...calibration possible"; } else { qDebug() << "...calibration not possible"; } return SanityCheckSamples(Measurements(type, false)); } bool Calibration::constructErrorTerms(Calibration::Type type) { if(type == Type::None) { resetErrorTerms(); return true; } if(!calculationPossible(type)) { return false; } qDebug() << "Constructing error terms for" << TypeToString(type) << "calibration"; bool isTRL = type == Type::TRL; double kit_minFreq = kit.minFreq(isTRL); double kit_maxFreq = kit.maxFreq(isTRL); if(minFreq < kit_minFreq || maxFreq > kit_maxFreq) { // Calkit does not support complete calibration range QString msg = QString("The calibration kit does not support the complete span.\n\n") + "The measured calibration data covers " + Unit::ToString(minFreq, "Hz", " kMG", 4) + " to " + Unit::ToString(maxFreq, "Hz", " kMG", 4) + ", however the calibration kit is only valid from " + Unit::ToString(kit_minFreq, "Hz", " kMG", 4) + " to " + Unit::ToString(kit_maxFreq, "Hz", " kMG", 4) + ".\n\n" + "Please adjust the calibration kit or the span and take the calibration measurements again."; QMessageBox::critical(nullptr, "Unable to perform calibration", msg); qWarning() << msg; return false; } switch(type) { case Type::Port1SOL: constructPort1SOL(); break; case Type::Port2SOL: constructPort2SOL(); break; case Type::FullSOLT: construct12TermPoints(); break; case Type::TransmissionNormalization: constructTransmissionNormalization(); break; case Type::TRL: constructTRL(); break; case Type::None: break; } this->type = type; return true; } void Calibration::resetErrorTerms() { type = Type::None; points.clear(); qDebug() << "Error terms reset"; } void Calibration::construct12TermPoints() { std::vector requiredMeasurements = Measurements(Type::FullSOLT); requiredMeasurements.push_back(Measurement::Isolation); bool isolation_measured = SanityCheckSamples(requiredMeasurements); points.clear(); for(unsigned int i = 0;i(measurements[Measurement::Port1Open].datapoints[i].real_S11, measurements[Measurement::Port1Open].datapoints[i].imag_S11); auto S11_short = complex(measurements[Measurement::Port1Short].datapoints[i].real_S11, measurements[Measurement::Port1Short].datapoints[i].imag_S11); auto S11_load = complex(measurements[Measurement::Port1Load].datapoints[i].real_S11, measurements[Measurement::Port1Load].datapoints[i].imag_S11); auto S22_open = complex(measurements[Measurement::Port2Open].datapoints[i].real_S22, measurements[Measurement::Port2Open].datapoints[i].imag_S22); auto S22_short = complex(measurements[Measurement::Port2Short].datapoints[i].real_S22, measurements[Measurement::Port2Short].datapoints[i].imag_S22); auto S22_load = complex(measurements[Measurement::Port2Load].datapoints[i].real_S22, measurements[Measurement::Port2Load].datapoints[i].imag_S22); auto S21_isolation = complex(0,0); auto S12_isolation = complex(0,0); if(isolation_measured) { S21_isolation = complex(measurements[Measurement::Isolation].datapoints[i].real_S21, measurements[Measurement::Isolation].datapoints[i].imag_S21); S12_isolation = complex(measurements[Measurement::Isolation].datapoints[i].real_S12, measurements[Measurement::Isolation].datapoints[i].imag_S12); } auto S11_through = complex(measurements[Measurement::Through].datapoints[i].real_S11, measurements[Measurement::Through].datapoints[i].imag_S11); auto S21_through = complex(measurements[Measurement::Through].datapoints[i].real_S21, measurements[Measurement::Through].datapoints[i].imag_S21); auto S22_through = complex(measurements[Measurement::Through].datapoints[i].real_S22, measurements[Measurement::Through].datapoints[i].imag_S22); auto S12_through = complex(measurements[Measurement::Through].datapoints[i].real_S12, measurements[Measurement::Through].datapoints[i].imag_S12); auto actual = kit.toSOLT(p.frequency); // Forward calibration computeSOL(S11_short, S11_open, S11_load, p.fe00, p.fe11, p.fe10e01, actual.Open, actual.Short, actual.Load); p.fe30 = S21_isolation; // See page 18 of https://www.rfmentor.com/sites/default/files/NA_Error_Models_and_Cal_Methods.pdf // Formulas for S11M and S21M solved for e22 and e10e32 auto deltaS = actual.ThroughS11*actual.ThroughS22 - actual.ThroughS21 * actual.ThroughS12; p.fe22 = ((S11_through - p.fe00)*(1.0 - p.fe11 * actual.ThroughS11)-actual.ThroughS11*p.fe10e01) / ((S11_through - p.fe00)*(actual.ThroughS22-p.fe11*deltaS)-deltaS*p.fe10e01); p.fe10e32 = (S21_through - p.fe30)*(1.0 - p.fe11*actual.ThroughS11 - p.fe22*actual.ThroughS22 + p.fe11*p.fe22*deltaS) / actual.ThroughS21; // Reverse calibration computeSOL(S22_short, S22_open, S22_load, p.re33, p.re22, p.re23e32, actual.Open, actual.Short, actual.Load); p.re03 = S12_isolation; p.re11 = ((S22_through - p.re33)*(1.0 - p.re22 * actual.ThroughS22)-actual.ThroughS22*p.re23e32) / ((S22_through - p.re33)*(actual.ThroughS11-p.re22*deltaS)-deltaS*p.re23e32); p.re23e01 = (S12_through - p.re03)*(1.0 - p.re11*actual.ThroughS11 - p.re22*actual.ThroughS22 + p.re11*p.re22*deltaS) / actual.ThroughS12; points.push_back(p); } } void Calibration::constructPort1SOL() { points.clear(); for(unsigned int i = 0;i(measurements[Measurement::Port1Open].datapoints[i].real_S11, measurements[Measurement::Port1Open].datapoints[i].imag_S11); auto S11_short = complex(measurements[Measurement::Port1Short].datapoints[i].real_S11, measurements[Measurement::Port1Short].datapoints[i].imag_S11); auto S11_load = complex(measurements[Measurement::Port1Load].datapoints[i].real_S11, measurements[Measurement::Port1Load].datapoints[i].imag_S11); // OSL port1 auto actual = kit.toSOLT(p.frequency); // See page 13 of https://www.rfmentor.com/sites/default/files/NA_Error_Models_and_Cal_Methods.pdf computeSOL(S11_short, S11_open, S11_load, p.fe00, p.fe11, p.fe10e01, actual.Open, actual.Short, actual.Load); // All other calibration coefficients to ideal values p.fe30 = 0.0; p.fe22 = 0.0; p.fe10e32 = 1.0; p.re33 = 0.0; p.re22 = 0.0; p.re23e32 = 1.0; p.re03 = 0.0; p.re11 = 0.0; p.re23e01 = 1.0; points.push_back(p); } } void Calibration::constructPort2SOL() { points.clear(); for(unsigned int i = 0;i(measurements[Measurement::Port2Open].datapoints[i].real_S22, measurements[Measurement::Port2Open].datapoints[i].imag_S22); auto S22_short = complex(measurements[Measurement::Port2Short].datapoints[i].real_S22, measurements[Measurement::Port2Short].datapoints[i].imag_S22); auto S22_load = complex(measurements[Measurement::Port2Load].datapoints[i].real_S22, measurements[Measurement::Port2Load].datapoints[i].imag_S22); // OSL port2 auto actual = kit.toSOLT(p.frequency); // See page 19 of https://www.rfmentor.com/sites/default/files/NA_Error_Models_and_Cal_Methods.pdf computeSOL(S22_short, S22_open, S22_load, p.re33, p.re22, p.re23e32, actual.Open, actual.Short, actual.Load); // All other calibration coefficients to ideal values p.fe30 = 0.0; p.fe22 = 0.0; p.fe10e32 = 1.0; p.fe00 = 0.0; p.fe11 = 0.0; p.fe10e01 = 1.0; p.re03 = 0.0; p.re11 = 0.0; p.re23e01 = 1.0; points.push_back(p); } } void Calibration::constructTransmissionNormalization() { points.clear(); for(unsigned int i = 0;i(measurements[Measurement::Through].datapoints[i].real_S21, measurements[Measurement::Through].datapoints[i].imag_S21); auto S12_through = complex(measurements[Measurement::Through].datapoints[i].real_S12, measurements[Measurement::Through].datapoints[i].imag_S12); auto actual = kit.toSOLT(p.frequency); p.fe10e32 = S21_through / actual.ThroughS21; p.re23e01 = S12_through / actual.ThroughS12; // All other calibration coefficients to ideal values p.fe30 = 0.0; p.fe22 = 0.0; p.fe00 = 0.0; p.fe11 = 0.0; p.fe10e01 = 1.0; p.re03 = 0.0; p.re11 = 0.0; p.re33 = 0.0; p.re22 = 0.0; p.re23e32 = 1.0; points.push_back(p); } } template class Tparam { public: Tparam(){}; Tparam(T t11, T t12, T t21, T t22) : t11(t11), t12(t12), t21(t21), t22(t22){}; void fromSparam(T S11, T S21, T S12, T S22) { t11 = -(S11*S22 - S12*S21) / S21; t12 = S11 / S21; t21 = -S22 / S21; t22 = 1.0 / S21; } void toSparam(T &S11, T &S21, T &S12, T &S22) { S11 = t12 / t22; S21 = T(1) / t22; S12 = (t11*t22 - t12*t21) / t22; S22 = -t21 / t22; } Tparam inverse() { Tparam i; T det = t11*t22 - t12*t21; i.t11 = t22 / det; i.t12 = -t12 / det; i.t21 = -t21 / det; i.t22 = t11 / det; return i; } Tparam operator*(const Tparam &r) { Tparam p; p.t11 = t11*r.t11 + t12*r.t21; p.t12 = t11*r.t12 + t12*r.t22; p.t21 = t21*r.t11 + t22*r.t21; p.t22 = t21*r.t12 + t22*r.t22; return p; } Tparam operator*(const T &r) { Tparam p; p.t11 = t11 * r; p.t12 = t12 * r; p.t21 = t21 * r; p.t22 = t22 * r; return p; } T t11, t12, t21, t22; }; template void solveQuadratic(T a, T b, T c, T &result1, T &result2) { T root = sqrt(b * b - T(4) * a * c); result1 = (-b + root) / (T(2) * a); result2 = (-b - root) / (T(2) * a); } void Calibration::constructTRL() { points.clear(); for(unsigned int i = 0;i(measurements[Measurement::Through].datapoints[i].real_S11, measurements[Measurement::Through].datapoints[i].imag_S11); auto S21_through = complex(measurements[Measurement::Through].datapoints[i].real_S21, measurements[Measurement::Through].datapoints[i].imag_S21); auto S22_through = complex(measurements[Measurement::Through].datapoints[i].real_S22, measurements[Measurement::Through].datapoints[i].imag_S22); auto S12_through = complex(measurements[Measurement::Through].datapoints[i].real_S12, measurements[Measurement::Through].datapoints[i].imag_S12); auto S11_line = complex(measurements[Measurement::Line].datapoints[i].real_S11, measurements[Measurement::Line].datapoints[i].imag_S11); auto S21_line = complex(measurements[Measurement::Line].datapoints[i].real_S21, measurements[Measurement::Line].datapoints[i].imag_S21); auto S22_line = complex(measurements[Measurement::Line].datapoints[i].real_S22, measurements[Measurement::Line].datapoints[i].imag_S22); auto S12_line = complex(measurements[Measurement::Line].datapoints[i].real_S12, measurements[Measurement::Line].datapoints[i].imag_S12); auto trl = kit.toTRL(p.frequency); complex S11_reflection, S22_reflection; if(trl.reflectionIsNegative) { // used short S11_reflection = complex(measurements[Measurement::Port1Short].datapoints[i].real_S11, measurements[Measurement::Port1Short].datapoints[i].imag_S11); S22_reflection = complex(measurements[Measurement::Port2Short].datapoints[i].real_S22, measurements[Measurement::Port2Short].datapoints[i].imag_S22); } else { // used open S11_reflection = complex(measurements[Measurement::Port1Open].datapoints[i].real_S11, measurements[Measurement::Port1Open].datapoints[i].imag_S11); S22_reflection = complex(measurements[Measurement::Port2Open].datapoints[i].real_S22, measurements[Measurement::Port2Open].datapoints[i].imag_S22); } // calculate TRL calibration // variable names and formulas according to http://emlab.uiuc.edu/ece451/notes/new_TRL.pdf // page 19 auto R_T = Tparam>(); auto R_D = Tparam>(); R_T.fromSparam(S11_through, S21_through, S12_through, S22_through); R_D.fromSparam(S11_line, S21_line, S12_line, S22_line); auto T = R_D*R_T.inverse(); complex a_over_c, b; // page 21-22 solveQuadratic(T.t21, T.t22 - T.t11, -T.t12, b, a_over_c); // ensure correct root selection // page 23 if(abs(b) >= abs(a_over_c)) { swap(b, a_over_c); } // page 24 auto g = R_T.t22; auto d = R_T.t11 / g; auto e = R_T.t12 / g; auto f = R_T.t21 / g; // page 25 auto r22_rho22 = g * (1.0 - e / a_over_c) / (1.0 - b / a_over_c); auto gamma = (f - d / a_over_c) / (1.0 - e / a_over_c); auto beta_over_alpha = (e - b) / (d - b * f); // page 26 auto alpha_a = (d - b * f) / (1.0 - e / a_over_c); auto w1 = S11_reflection; auto w2 = S22_reflection; // page 28 auto a = sqrt((w1 - b) / (w2 + gamma) * (1.0 + w2 * beta_over_alpha) / (1.0 - w1 / a_over_c) * alpha_a); // page 29, check sign of a auto reflection = (w1 - b) / (a * (1.0 - w1 / a_over_c)); if((reflection.real() > 0 && trl.reflectionIsNegative) || (reflection.real() < 0 && !trl.reflectionIsNegative)) { // wrong sign for a a = -a; } // Revert back from error boxes with T parameters to S paramaters, // page 17 + formulas for calculating S parameters from T parameters. // Forward coefficients, normalize for S21 = 1.0 -> r22 = 1.0 auto r22 = complex(1.0); auto rho22 = r22_rho22 / r22; auto alpha = alpha_a / a; auto beta = beta_over_alpha * alpha; auto c = a / a_over_c; auto Box_A = Tparam>(r22 * a, r22 * b, r22 * c, r22); auto Box_B = Tparam>(rho22 * alpha, rho22 * beta, rho22 * gamma, rho22); complex dummy1, dummy2; Box_A.toSparam(p.fe00, dummy1, p.fe10e01, p.fe11); Box_B.toSparam(p.fe22, p.fe10e32, dummy1, dummy2); // no isolation measurement available p.fe30 = 0.0; // Reverse coefficients, normalize for S12 = 1.0 // => det(T)/T22 = 1.0 // => (rho22*alpa*rho22 - rho22*beta*rho*gamma)/rho22 = 1.0 // => rho22*alpha - rho22*beta*gamma = 1.0 // => rho22 = 1.0/(alpha - beta * gamma) rho22 = 1.0/(alpha - beta * gamma); r22 = r22_rho22 / rho22; Box_A = Tparam>(r22 * a, r22 * b, r22 * c, r22); Box_B = Tparam>(rho22 * alpha, rho22 * beta, rho22 * gamma, rho22); Box_A.toSparam(dummy1, dummy2, p.re23e01, p.re11); Box_B.toSparam(p.re22, p.re23e32, dummy1, p.re33); // no isolation measurement available p.re03 = 0.0; points.push_back(p); } } void Calibration::correctMeasurement(Protocol::Datapoint &d) { if(type == Type::None) { // No calibration data, do nothing return; } // Convert measurements to complex variables auto S11m = complex(d.real_S11, d.imag_S11); auto S21m = complex(d.real_S21, d.imag_S21); auto S22m = complex(d.real_S22, d.imag_S22); auto S12m = complex(d.real_S12, d.imag_S12); // find correct entry auto p = getCalibrationPoint(d); complex S11, S12, S21, S22; // equations from page 19 of https://www.rfmentor.com/sites/default/files/NA_Error_Models_and_Cal_Methods.pdf auto denom = (1.0 + (S11m - p.fe00) / p.fe10e01 * p.fe11) * (1.0 + (S22m - p.re33) / p.re23e32 * p.re22) - (S21m - p.fe30) / p.fe10e32 * (S12m - p.re03) / p.re23e01 * p.fe22 * p.re11; S11 = ((S11m - p.fe00) / p.fe10e01 * (1.0 + (S22m - p.re33) / p.re23e32 * p.re22) - p.fe22 * (S21m - p.fe30) / p.fe10e32 * (S12m - p.re03) / p.re23e01) / denom; S21 = ((S21m - p.fe30) / p.fe10e32 * (1.0 + (S22m - p.re33) / p.re23e32 * (p.re22 - p.fe22))) / denom; S22 = ((S22m - p.re33) / p.re23e32 * (1.0 + (S11m - p.fe00) / p.fe10e01 * p.fe11) - p.re11 * (S21m - p.fe30) / p.fe10e32 * (S12m - p.re03) / p.re23e01) / denom; S12 = ((S12m - p.re03) / p.re23e01 * (1.0 + (S11m - p.fe00) / p.fe10e01 * (p.fe11 - p.re11))) / denom; d.real_S11 = S11.real(); d.imag_S11 = S11.imag(); d.real_S12 = S12.real(); d.imag_S12 = S12.imag(); d.real_S21 = S21.real(); d.imag_S21 = S21.imag(); d.real_S22 = S22.real(); d.imag_S22 = S22.imag(); } Calibration::InterpolationType Calibration::getInterpolation(Protocol::SweepSettings settings) { if(!points.size()) { return InterpolationType::NoCalibration; } if(settings.f_start < points.front().frequency || settings.f_stop > points.back().frequency) { return InterpolationType::Extrapolate; } // Either exact or interpolation, check individual frequencies uint32_t f_step; if(settings.points > 1) { f_step = (settings.f_stop - settings.f_start) / (settings.points - 1); } else { f_step = settings.f_stop - settings.f_start; } for(uint64_t f = settings.f_start; f <= settings.f_stop; f += f_step) { if(find_if(points.begin(), points.end(), [&f](const Point& p){ return abs(f - p.frequency) < 100; }) == points.end()) { return InterpolationType::Interpolate; } } // if we get here all frequency points were matched if(points.front().frequency == settings.f_start && points.back().frequency == settings.f_stop) { return InterpolationType::Unchanged; } else { return InterpolationType::Exact; } } QString Calibration::MeasurementToString(Calibration::Measurement m) { switch(m) { case Measurement::Port1Open: return "Port 1 Open"; case Measurement::Port1Short: return "Port 1 Short"; case Measurement::Port1Load: return "Port 1 Load"; case Measurement::Port2Open: return "Port 2 Open"; case Measurement::Port2Short: return "Port 2 Short"; case Measurement::Port2Load: return "Port 2 Load"; case Measurement::Through: return "Through"; case Measurement::Isolation: return "Isolation"; case Measurement::Line: return "Line"; default: return "Unknown"; } } QString Calibration::TypeToString(Calibration::Type t) { switch(t) { case Type::Port1SOL: return "Port 1"; break; case Type::Port2SOL: return "Port 2"; break; case Type::FullSOLT: return "SOLT"; break; case Type::TransmissionNormalization: return "Normalize"; break; case Type::TRL: return "TRL"; break; default: return "None"; break; } } const std::vector Calibration::Types() { const std::vector ret = {Type::Port1SOL, Type::Port2SOL, Type::FullSOLT, Type::TransmissionNormalization, Type::TRL}; return ret; } const std::vector Calibration::Measurements(Calibration::Type type, bool optional_included) { switch(type) { case Type::None: // all possible measurements return {Measurement::Port1Short, Measurement::Port1Open, Measurement::Port1Load, Measurement::Port2Short, Measurement::Port2Open, Measurement::Port2Load, Measurement::Through, Measurement::Isolation, Measurement::Line}; case Type::FullSOLT: if(optional_included) { return {Measurement::Port1Short, Measurement::Port1Open, Measurement::Port1Load, Measurement::Port2Short, Measurement::Port2Open, Measurement::Port2Load, Measurement::Through, Measurement::Isolation}; } else { return {Measurement::Port1Short, Measurement::Port1Open, Measurement::Port1Load, Measurement::Port2Short, Measurement::Port2Open, Measurement::Port2Load, Measurement::Through}; } break; case Type::Port1SOL: return {Measurement::Port1Short, Measurement::Port1Open, Measurement::Port1Load}; break; case Type::Port2SOL: return {Measurement::Port2Short, Measurement::Port2Open, Measurement::Port2Load}; break; case Type::TransmissionNormalization: return {Measurement::Through}; break; case Type::TRL: if(kit.isTRLReflectionShort()) { return {Measurement::Through, Measurement::Port1Short, Measurement::Port2Short, Measurement::Line}; } else { return {Measurement::Through, Measurement::Port1Open, Measurement::Port2Open, Measurement::Line}; } break; default: return {}; break; } } Calibration::MeasurementInfo Calibration::getMeasurementInfo(Calibration::Measurement m) { MeasurementInfo info; switch(m) { case Measurement::Port1Short: info.name = "Port 1 short"; info.prerequisites = "Short standard connected to port 1, port 2 open"; break; case Measurement::Port1Open: info.name = "Port 1 open"; info.prerequisites = "Open standard connected to port 1, port 2 open"; break; case Measurement::Port1Load: info.name = "Port 1 load"; info.prerequisites = "Load standard connected to port 1, port 2 open"; break; case Measurement::Port2Short: info.name = "Port 2 short"; info.prerequisites = "Port 1 open, short standard connected to port 2"; break; case Measurement::Port2Open: info.name = "Port 2 open"; info.prerequisites = "Port 1 open, open standard connected to port 2"; break; case Measurement::Port2Load: info.name = "Port 2 load"; info.prerequisites = "Port 1 open, load standard connected to port 2"; break; case Measurement::Through: info.name = "Through"; info.prerequisites = "Port 1 connected to port 2 via through standard"; break; case Measurement::Isolation: info.name = "Isolation"; info.prerequisites = "Both ports terminated into 50 ohm"; break; case Measurement::Line: info.name = "Line"; info.prerequisites = "Port 1 connected to port 2 via line standard"; break; } info.points = measurements[m].datapoints.size(); if(info.points > 0) { info.fmin = measurements[m].datapoints.front().frequency; info.fmax = measurements[m].datapoints.back().frequency; info.points = measurements[m].datapoints.size(); } info.timestamp = measurements[m].timestamp; return info; } std::vector Calibration::getErrorTermTraces() { std::vector traces; const QString traceNames[12] = {"e00", "F_e11", "e10e01", "e10e32", "F_e22", "e30", "e33", "R_e11", "e23e32", "e23e01", "R_e22", "e03"}; constexpr bool reflection[12] = {true, true, false, false, true, false, true, true, false, false, true, false}; for(int i=0;i<12;i++) { auto t = new Trace(traceNames[i], Qt::red); t->setCalibration(true); t->setReflection(reflection[i]); traces.push_back(t); } for(auto p : points) { Trace::Data d; d.x = p.frequency; for(int i=0;i<12;i++) { switch(i) { case 0: d.y = p.fe00; break; case 1: d.y = p.fe11; break; case 2: d.y = p.fe10e01; break; case 3: d.y = p.fe10e32; break; case 4: d.y = p.fe22; break; case 5: d.y = p.fe30; break; case 6: d.y = p.re33; break; case 7: d.y = p.re11; break; case 8: d.y = p.re23e32; break; case 9: d.y = p.re23e01; break; case 10: d.y = p.re22; break; case 11: d.y = p.re03; break; } traces[i]->addData(d); } } return traces; } std::vector Calibration::getMeasurementTraces() { std::vector traces; for(auto m : measurements) { auto info = getMeasurementInfo(m.first); if(info.points > 0) { vector usedPrefixes; switch(m.first) { case Measurement::Port1Load: case Measurement::Port1Open: case Measurement::Port1Short: usedPrefixes = {"S11"}; break; case Measurement::Port2Load: case Measurement::Port2Open: case Measurement::Port2Short: usedPrefixes = {"S22"}; break; case Measurement::Through: case Measurement::Line: case Measurement::Isolation: usedPrefixes = {"S11", "S12", "S21", "S22"}; break; } for(auto prefix : usedPrefixes) { auto t = new Trace(prefix + " " + info.name); t->setCalibration(true); t->setReflection(prefix == "S11" || prefix == "S22"); for(auto p : m.second.datapoints) { Trace::Data d; d.x = p.frequency; if(prefix == "S11") { d.y = complex(p.real_S11, p.imag_S11); } else if(prefix == "S12") { d.y = complex(p.real_S12, p.imag_S12); } else if(prefix == "S21") { d.y = complex(p.real_S21, p.imag_S21); } else { d.y = complex(p.real_S22, p.imag_S22); } t->addData(d); } traces.push_back(t); } } } return traces; } bool Calibration::openFromFile(QString filename) { if(filename.isEmpty()) { filename = QFileDialog::getOpenFileName(nullptr, "Load calibration data", "", "Calibration files (*.cal)", nullptr, QFileDialog::DontUseNativeDialog); if(filename.isEmpty()) { // aborted selection return false; } } qDebug() << "Attempting to open calibration from file" << filename; // reset all data before loading new calibration clearMeasurements(); resetErrorTerms(); // attempt to load associated calibration kit first (needs to be available when performing calibration) auto calkit_file = filename; auto dotPos = calkit_file.lastIndexOf('.'); if(dotPos >= 0) { calkit_file.truncate(dotPos); } calkit_file.append(".calkit"); qDebug() << "Associated calibration kit expected in" << calkit_file; try { kit = Calkit::fromFile(calkit_file); } catch (runtime_error e) { QMessageBox::warning(nullptr, "Missing calibration kit", "The calibration kit file associated with the selected calibration could not be parsed. The calibration might not be accurate. (" + QString(e.what()) + ")"); qWarning() << "Parsing of calibration kit failed while opening calibration file: " << e.what(); } ifstream file; file.open(filename.toStdString()); try { file >> *this; } catch(runtime_error e) { QMessageBox::warning(nullptr, "File parsing error", e.what()); qWarning() << "Calibration file parsing failed: " << e.what(); return false; } return true; } bool Calibration::saveToFile(QString filename) { if(filename.isEmpty()) { filename = QFileDialog::getSaveFileName(nullptr, "Save calibration data", "", "Calibration files (*.cal)", nullptr, QFileDialog::DontUseNativeDialog); if(filename.isEmpty()) { // aborted selection return false; } } if(filename.endsWith(".cal")) { filename.chop(4); } auto calibration_file = filename + ".cal"; ofstream file; file.open(calibration_file.toStdString()); file << *this; auto calkit_file = filename + ".calkit"; qDebug() << "Saving associated calibration kit to file" << calkit_file; kit.toFile(calkit_file); return true; } ostream& operator<<(ostream &os, const Calibration &c) { for(auto m : c.measurements) { if(m.second.datapoints.size() > 0) { os << c.MeasurementToString(m.first).toStdString() << endl; os << m.second.timestamp.toSecsSinceEpoch() << endl; os << m.second.datapoints.size() << endl; for(auto p : m.second.datapoints) { os << p.pointNum << " " << p.frequency << " "; os << p.imag_S11 << " " << p.real_S11 << " " << p.imag_S21 << " " << p.real_S21 << " " << p.imag_S12 << " " << p.real_S12 << " " << p.imag_S22 << " " << p.real_S22; os << endl; } } } os << Calibration::TypeToString(c.getType()).toStdString() << endl; return os; } istream& operator >>(istream &in, Calibration &c) { std::string line; while(getline(in, line)) { QString qLine = QString::fromStdString(line).simplified(); for(auto m : c.Measurements()) { if(Calibration::MeasurementToString(m) == qLine) { // this is the correct measurement c.measurements[m].datapoints.clear(); uint timestamp; in >> timestamp; c.measurements[m].timestamp = QDateTime::fromSecsSinceEpoch(timestamp); unsigned int points; in >> points; qDebug() << "Found measurement" << Calibration::MeasurementToString(m) << ", containing" << points << "points"; for(unsigned int i=0;i> p.pointNum >> p.frequency; in >> p.imag_S11 >> p.real_S11 >> p.imag_S21 >> p.real_S21 >> p.imag_S12 >> p.real_S12 >> p.imag_S22 >> p.real_S22; c.measurements[m].datapoints.push_back(p); if(in.eof() || in.bad() || in.fail()) { c.clearMeasurement(m); throw runtime_error("Failed to parse measurement \"" + line + "\", aborting calibration data import."); } } break; } } for(auto t : Calibration::Types()) { if(Calibration::TypeToString(t) == qLine) { // try to apply this calibration type qDebug() << "Specified calibration in file is" << Calibration::TypeToString(t); if(c.calculationPossible(t)) { c.constructErrorTerms(t); } else { throw runtime_error("Incomplete calibration data, the requested \"" + line + "\"-Calibration could not be performed."); } break; } } } qDebug() << "Calibration file parsing complete"; return in; } bool Calibration::SanityCheckSamples(const std::vector &requiredMeasurements) { // sanity check measurements, all need to be of the same size with the same frequencies (except for isolation which may be empty) vector freqs; for(auto type : requiredMeasurements) { auto m = measurements[type]; if(m.datapoints.size() == 0) { // empty required measurement return false; } if(freqs.size() == 0) { // this is the first measurement, create frequency vector for(auto p : m.datapoints) { freqs.push_back(p.frequency); } } else { // compare with already assembled frequency vector if(m.datapoints.size() != freqs.size()) { return false; } for(unsigned int i=0;i= points.back().frequency) { // use last point even for higher frequencies return points.back(); } auto p = lower_bound(points.begin(), points.end(), d.frequency, [](Point p, uint64_t freq) -> bool { return p.frequency < freq; }); if(p->frequency == d.frequency) { // Exact match, return point return *p; } // need to interpolate auto high = p; p--; auto low = p; double alpha = (d.frequency - low->frequency) / (high->frequency - low->frequency); Point ret; ret.frequency = d.frequency; ret.fe00 = low->fe00 * (1 - alpha) + high->fe00 * alpha; ret.fe11 = low->fe11 * (1 - alpha) + high->fe11 * alpha; ret.fe22 = low->fe22 * (1 - alpha) + high->fe22 * alpha; ret.fe30 = low->fe30 * (1 - alpha) + high->fe30 * alpha; ret.re03 = low->re03 * (1 - alpha) + high->re03 * alpha; ret.re11 = low->re11 * (1 - alpha) + high->re11 * alpha; ret.re22 = low->re22 * (1 - alpha) + high->re22 * alpha; ret.re33 = low->re33 * (1 - alpha) + high->re33 * alpha; ret.fe10e01 = low->fe10e01 * (1 - alpha) + high->fe10e01 * alpha; ret.fe10e32 = low->fe10e32 * (1 - alpha) + high->fe10e32 * alpha; ret.re23e01 = low->re23e01 * (1 - alpha) + high->re23e01 * alpha; ret.re23e32 = low->re23e32 * (1 - alpha) + high->re23e32 * alpha; return ret; } void Calibration::computeSOL(std::complex s_m, std::complex o_m, std::complex l_m, std::complex &directivity, std::complex &match, std::complex &tracking, std::complex o_c, std::complex s_c, std::complex l_c) { // equations from page 13 of http://www2.electron.frba.utn.edu.ar/~jcecconi/Bibliografia/04%20-%20Param_S_y_VNA/Network_Analyzer_Error_Models_and_Calibration_Methods.pdf // solved while taking non ideal o/s/l standards into account auto denom = l_c * o_c * (o_m - l_m) + l_c * s_c * (l_m - s_m) + o_c * s_c * (s_m - o_m); directivity = (l_c * o_m * (s_m * (o_c - s_c) + l_m * s_c) - l_c * o_c * l_m * s_m + o_c * l_m * s_c * (s_m - o_m)) / denom; match = (l_c * (o_m - s_m) + o_c * (s_m - l_m) + s_c * (l_m - o_m)) / denom; auto delta = (l_c * l_m * (o_m - s_m) + o_c * o_m * (s_m - l_m) + s_c * s_m * (l_m - o_m)) / denom; tracking = directivity * match - delta; } std::complex Calibration::correctSOL(std::complex measured, std::complex directivity, std::complex match, std::complex tracking) { return (measured - directivity) / (measured * match - directivity * match + tracking); } Calkit &Calibration::getCalibrationKit() { return kit; } void Calibration::setCalibrationKit(const Calkit &value) { kit = value; } Calibration::Type Calibration::getType() const { return type; }