#include #include "../src/mesomie.hpp" #include "../src/nmie-basic.hpp" #include "gtest/gtest.h" // TODO fails for MP with 100 digits. And 16 digits, which should be equal to // double precision. #ifndef MULTI_PRECISION // TEST(BulkSphere, DISABLED_ArgPi) { //****************************************************************************** TEST(BulkSphere, ArgPi) { std::vector WLs{50, 80, 100, 200, 400}; // nm double host_index = 2.; double core_radius = 100.; // nm double delta = 1e-5; nmie::MultiLayerMie nmie; nmie.SetLayersIndex({std::complex(4, 0)}); for (auto WL : WLs) { nmie.SetLayersSize( {2 * nmie::PI_ * host_index * core_radius / (WL + delta)}); nmie.RunMieCalculation(); double Qabs_p = std::abs(static_cast(nmie.GetQabs())); nmie.SetLayersSize( {2 * nmie::PI_ * host_index * core_radius / (WL - delta)}); nmie.RunMieCalculation(); double Qabs_m = std::abs(static_cast(nmie.GetQabs())); nmie.SetLayersSize({2 * nmie::PI_ * host_index * core_radius / (WL)}); nmie.RunMieCalculation(); double Qabs = std::abs(static_cast(nmie.GetQabs())); EXPECT_GT(Qabs_p + Qabs_m, Qabs); } } #endif //****************************************************************************** // A list of tests for a bulk sphere from // Hong Du, "Mie-scattering calculation," Appl. Opt. 43, 1951-1956 (2004) // table 1: sphere size and refractive index // followed by resulting extinction and scattering efficiencies std::vector, double, double, char> > parameters_and_results{ // x, {Re(m), Im(m)}, Qext, Qsca, test_name {0.099, {0.75, 0}, 7.417859e-06, 7.417859e-06, 'a'}, {0.101, {0.75, 0}, 8.033538e-06, 8.033538e-06, 'b'}, {10, {0.75, 0}, 2.232265, 2.232265, 'c'}, {0.055, {1.5, 1}, 0.10149104, 1.131687e-05, 'g'}, {0.056, {1.5, 1}, 0.1033467, 1.216311e-05, 'h'}, {1, {10, 10}, 2.532993, 2.049405, 'k'}, {100, {1.33, 1e-5}, 2.101321, 2.096594, 'e'}, {100, {1.5, 1}, 2.097502, 1.283697, 'i'}, {1000, {0.75, 0}, 1.997908, 1.997908, 'd'}, {100, {10, 10}, 2.071124, 1.836785, 'l'}, {10000, {1.33, 1e-5}, 2.004089, 1.723857, 'f'}, {10000, {1.5, 1}, 2.004368, 1.236574, 'j'}, {10000, {10, 10}, 2.005914, 1.795393, 'm'}, }; //****************************************************************************** // TEST(BulkSphere, DISABLED_HandlesInput) { TEST(BulkSphere, MultiLayerDu) { nmie::MultiLayerMie nmie; for (const auto& data : parameters_and_results) { auto x = std::get<0>(data); auto m = std::get<1>(data); // auto Nstop = nmie::LeRu_near_field_cutoff(m*x)+1; nmie.SetLayersSize({x}); nmie.SetLayersIndex({m}); // nmie.SetMaxTerms(Nstop); nmie.RunMieCalculation(); double Qext = static_cast(nmie.GetQext()); double Qsca = static_cast(nmie.GetQsca()); double Qext_Du = std::get<2>(data); double Qsca_Du = std::get<3>(data); EXPECT_FLOAT_EQ(Qext_Du, Qext) << "Extinction of the bulk sphere, test case:" << std::get<4>(data) << "\nnmax_ = " << nmie.GetMaxTerms(); EXPECT_FLOAT_EQ(Qsca_Du, Qsca) << "Scattering of the bulk sphere, test case:" << std::get<4>(data); } } //****************************************************************************** TEST(BulkSphere, MesoMieDu) { nmie::MultiLayerMie nmie; nmie::MesoMie mesomie; for (const auto& data : parameters_and_results) { auto x = std::get<0>(data); auto m = std::get<1>(data); mesomie.calc_ab(x, // R {x, 0}, // xd x * m, // xm {1, 0}, // eps_d m * m, // eps_m {0, 0}, // d_parallel {0, 0}); // d_perp mesomie.calc_Q(); double Qext = static_cast(mesomie.GetQext()); double Qsca = static_cast(mesomie.GetQsca()); double Qext_Du = std::get<2>(data); double Qsca_Du = std::get<3>(data); EXPECT_FLOAT_EQ(Qext_Du, Qext) << "Extinction of the bulk sphere, test case:" << std::get<4>(data) << "\nnmax_ = " << nmie.GetMaxTerms(); EXPECT_FLOAT_EQ(Qsca_Du, Qsca) << "Scattering of the bulk sphere, test case:" << std::get<4>(data); } } int main(int argc, char** argv) { testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }