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370 lines
12 KiB
C++
370 lines
12 KiB
C++
//
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// NumericalAnalysis.cpp
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//
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// Created by Marc Melikyan on 11/13/20.
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//
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#include "numerical_analysis.h"
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#include "../lin_alg/lin_alg.h"
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#include "../lin_alg/mlpp_matrix.h"
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#include "../lin_alg/mlpp_tensor3.h"
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#include "../lin_alg/mlpp_vector.h"
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real_t MLPPNumericalAnalysis::num_diffr(real_t (*function)(real_t), real_t x) {
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real_t eps = 1e-10;
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return (function(x + eps) - function(x)) / eps; // This is just the formal def. of the derivative.
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}
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real_t MLPPNumericalAnalysis::num_diff_2r(real_t (*function)(real_t), real_t x) {
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real_t eps = 1e-5;
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return (function(x + 2 * eps) - 2 * function(x + eps) + function(x)) / (eps * eps);
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}
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real_t MLPPNumericalAnalysis::num_diff_3r(real_t (*function)(real_t), real_t x) {
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real_t eps = 1e-5;
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real_t t1 = function(x + 3 * eps) - 2 * function(x + 2 * eps) + function(x + eps);
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real_t t2 = function(x + 2 * eps) - 2 * function(x + eps) + function(x);
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return (t1 - t2) / (eps * eps * eps);
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}
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real_t MLPPNumericalAnalysis::constant_approximationr(real_t (*function)(real_t), real_t c) {
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return function(c);
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}
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real_t MLPPNumericalAnalysis::linear_approximationr(real_t (*function)(real_t), real_t c, real_t x) {
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return constant_approximationr(function, c) + num_diffr(function, c) * (x - c);
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}
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real_t MLPPNumericalAnalysis::quadratic_approximationr(real_t (*function)(real_t), real_t c, real_t x) {
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return linear_approximationr(function, c, x) + 0.5 * num_diff_2r(function, c) * (x - c) * (x - c);
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}
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real_t MLPPNumericalAnalysis::cubic_approximationr(real_t (*function)(real_t), real_t c, real_t x) {
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return quadratic_approximationr(function, c, x) + (1 / 6) * num_diff_3r(function, c) * (x - c) * (x - c) * (x - c);
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}
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real_t MLPPNumericalAnalysis::num_diffv(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x, int axis) {
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// For multivariable function analysis.
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// This will be used for calculating Jacobian vectors.
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// Diffrentiate with respect to indicated axis. (0, 1, 2 ...)
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real_t eps = 1e-10;
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Ref<MLPPVector> x_eps = x->duplicate_fast();
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x_eps->element_get_ref(axis) += eps;
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return (function(x_eps) - function(x)) / eps;
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}
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real_t MLPPNumericalAnalysis::num_diff_2v(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x, int axis1, int axis2) {
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//For Hessians.
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real_t eps = 1e-5;
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Ref<MLPPVector> x_pp = x->duplicate_fast();
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x_pp->element_get_ref(axis1) += eps;
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x_pp->element_get_ref(axis2) += eps;
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Ref<MLPPVector> x_np = x->duplicate_fast();
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x_np->element_get_ref(axis2) += eps;
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Ref<MLPPVector> x_pn = x->duplicate_fast();
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x_pn->element_get_ref(axis1) += eps;
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return (function(x_pp) - function(x_np) - function(x_pn) + function(x)) / (eps * eps);
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}
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real_t MLPPNumericalAnalysis::num_diff_3v(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x, int axis1, int axis2, int axis3) {
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// For third order derivative tensors.
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// NOTE: Approximations do not appear to be accurate for sinusodial functions...
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// Should revisit this later.
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real_t eps = 1e-5;
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Ref<MLPPVector> x_ppp = x->duplicate_fast();
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x_ppp->element_get_ref(axis1) += eps;
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x_ppp->element_get_ref(axis2) += eps;
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x_ppp->element_get_ref(axis3) += eps;
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Ref<MLPPVector> x_npp = x->duplicate_fast();
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x_npp->element_get_ref(axis2) += eps;
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x_npp->element_get_ref(axis3) += eps;
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Ref<MLPPVector> x_pnp = x->duplicate_fast();
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x_pnp->element_get_ref(axis1) += eps;
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x_pnp->element_get_ref(axis3) += eps;
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Ref<MLPPVector> x_nnp = x->duplicate_fast();
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x_nnp->element_get_ref(axis3) += eps;
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Ref<MLPPVector> x_ppn = x->duplicate_fast();
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x_ppn->element_get_ref(axis1) += eps;
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x_ppn->element_get_ref(axis2) += eps;
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Ref<MLPPVector> x_npn = x->duplicate_fast();
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x_npn->element_get_ref(axis2) += eps;
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Ref<MLPPVector> x_pnn = x->duplicate_fast();
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x_pnn->element_get_ref(axis1) += eps;
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real_t thirdAxis = function(x_ppp) - function(x_npp) - function(x_pnp) + function(x_nnp);
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real_t noThirdAxis = function(x_ppn) - function(x_npn) - function(x_pnn) + function(x);
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return (thirdAxis - noThirdAxis) / (eps * eps * eps);
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}
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real_t MLPPNumericalAnalysis::newton_raphson_method(real_t (*function)(real_t), real_t x_0, real_t epoch_num) {
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real_t x = x_0;
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for (int i = 0; i < epoch_num; i++) {
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x -= function(x) / num_diffr(function, x);
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}
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return x;
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}
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real_t MLPPNumericalAnalysis::halley_method(real_t (*function)(real_t), real_t x_0, real_t epoch_num) {
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real_t x = x_0;
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for (int i = 0; i < epoch_num; i++) {
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x -= ((2 * function(x) * num_diffr(function, x)) / (2 * num_diffr(function, x) * num_diffr(function, x) - function(x) * num_diff_2r(function, x)));
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}
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return x;
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}
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real_t MLPPNumericalAnalysis::inv_quadratic_interpolation(real_t (*function)(real_t), const Ref<MLPPVector> &x_0, int epoch_num) {
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real_t x = 0;
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Ref<MLPPVector> ct = x_0->duplicate_fast();
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MLPPVector ¤t_three = *(ct.ptr());
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for (int i = 0; i < epoch_num; i++) {
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real_t t1 = ((function(current_three[1]) * function(current_three[2])) / ((function(current_three[0]) - function(current_three[1])) * (function(current_three[0]) - function(current_three[2])))) * current_three[0];
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real_t t2 = ((function(current_three[0]) * function(current_three[2])) / ((function(current_three[1]) - function(current_three[0])) * (function(current_three[1]) - function(current_three[2])))) * current_three[1];
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real_t t3 = ((function(current_three[0]) * function(current_three[1])) / ((function(current_three[2]) - function(current_three[0])) * (function(current_three[2]) - function(current_three[1])))) * current_three[2];
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x = t1 + t2 + t3;
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current_three.remove(0);
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current_three.push_back(x);
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}
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return x;
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}
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real_t MLPPNumericalAnalysis::eulerian_methodr(real_t (*derivative)(real_t), real_t q_0, real_t q_1, real_t p, real_t h) {
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int max_epoch = static_cast<int>((p - q_0) / h);
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real_t x = q_0;
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real_t y = q_1;
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for (int i = 0; i < max_epoch; i++) {
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y = y + h * derivative(x);
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x += h;
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}
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return y;
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}
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real_t MLPPNumericalAnalysis::eulerian_methodv(real_t (*derivative)(const Ref<MLPPVector> &), real_t q_0, real_t q_1, real_t p, real_t h) {
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int max_epoch = static_cast<int>((p - q_0) / h);
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Ref<MLPPVector> v;
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v.instance();
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v->resize(2);
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real_t x = q_0;
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real_t y = q_1;
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for (int i = 0; i < max_epoch; i++) {
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v->element_set(0, x);
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v->element_set(1, y);
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y = y + h * derivative(v);
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x += h;
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}
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return y;
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}
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real_t MLPPNumericalAnalysis::growth_method(real_t C, real_t k, real_t t) {
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//dP/dt = kP
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//dP/P = kdt
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//integral(1/P)dP = integral(k) dt
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//ln|P| = kt + C_initial
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//|P| = e^(kt + C_initial)
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//|P| = e^(C_initial) * e^(kt)
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//P = +/- e^(C_initial) * e^(kt)
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//P = C * e^(kt)
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// auto growthFunction = [&C, &k](real_t t) { return C * exp(k * t); };
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return C * Math::exp(k * t);
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}
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Ref<MLPPVector> MLPPNumericalAnalysis::jacobian(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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Ref<MLPPVector> jacobian;
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jacobian.instance();
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jacobian->resize(x->size());
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int jacobian_size = jacobian->size();
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for (int i = 0; i < jacobian_size; ++i) {
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jacobian->element_set(i, num_diffv(function, x, i)); // Derivative w.r.t axis i evaluated at x. For all x_i.
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}
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return jacobian;
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}
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Ref<MLPPMatrix> MLPPNumericalAnalysis::hessian(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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Ref<MLPPMatrix> hessian;
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hessian.instance();
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hessian->resize(Size2i(x->size(), x->size()));
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Size2i hessian_size = hessian->size();
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for (int i = 0; i < hessian_size.y; i++) {
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for (int j = 0; j < hessian_size.x; j++) {
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hessian->element_set(i, j, num_diff_2v(function, x, i, j));
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}
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}
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return hessian;
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}
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Ref<MLPPTensor3> MLPPNumericalAnalysis::third_order_tensor(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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Ref<MLPPTensor3> tensor;
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tensor.instance();
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tensor->resize(Size3i(x->size(), x->size(), x->size()));
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Size3i tensor_size = tensor->size();
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for (int i = 0; i < tensor_size.z; i++) { // O(n^3) time complexity :(
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for (int j = 0; j < tensor_size.y; j++) {
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for (int k = 0; k < tensor_size.x; k++)
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tensor->element_set(i, j, k, num_diff_3v(function, x, i, j, k));
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}
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}
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return tensor;
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}
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Vector<Ref<MLPPMatrix>> MLPPNumericalAnalysis::third_order_tensorvt(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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int x_size = x->size();
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Vector<Ref<MLPPMatrix>> tensor;
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tensor.resize(x_size);
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for (int i = 0; i < tensor.size(); i++) {
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Ref<MLPPMatrix> m;
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m.instance();
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m->resize(Size2i(x_size, x_size));
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tensor.write[i] = m;
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}
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for (int i = 0; i < tensor.size(); i++) { // O(n^3) time complexity :(
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Ref<MLPPMatrix> m = tensor[i];
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for (int j = 0; j < x_size; j++) {
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for (int k = 0; k < x_size; k++) {
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m->element_set(j, k, num_diff_3v(function, x, i, j, k));
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}
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}
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}
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return tensor;
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}
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real_t MLPPNumericalAnalysis::constant_approximationv(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &c) {
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return function(c);
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}
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real_t MLPPNumericalAnalysis::linear_approximationv(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &c, const Ref<MLPPVector> &x) {
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MLPPLinAlg alg;
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Ref<MLPPVector> j = jacobian(function, c);
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Ref<MLPPMatrix> mj;
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mj.instance();
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mj->row_add_mlpp_vector(j);
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Ref<MLPPVector> xsc = x->subn(c);
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Ref<MLPPMatrix> mxsc;
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mxsc.instance();
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mxsc->row_add_mlpp_vector(xsc);
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Ref<MLPPMatrix> m = mj->transposen()->multn(mxsc);
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return constant_approximationv(function, c) + m->element_get(0, 0);
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}
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real_t MLPPNumericalAnalysis::quadratic_approximationv(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &c, const Ref<MLPPVector> &x) {
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MLPPLinAlg alg;
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Ref<MLPPMatrix> h = hessian(function, c);
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Ref<MLPPVector> xsc = x->subn(c);
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Ref<MLPPMatrix> mxsc;
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mxsc.instance();
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mxsc->row_add_mlpp_vector(xsc);
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Ref<MLPPMatrix> r = mxsc->multn(h->multn(mxsc->transposen()));
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return linear_approximationv(function, c, x) + 0.5 * r->element_get(0, 0);
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}
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real_t MLPPNumericalAnalysis::cubic_approximationv(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &c, const Ref<MLPPVector> &x) {
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//Not completely sure as the literature seldom discusses the third order taylor approximation,
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//in particular for multivariate cases, but ostensibly, the matrix/tensor/vector multiplies
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//should look something like this:
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//(N x N x N) (N x 1) [tensor vector mult] => (N x N x 1) => (N x N)
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//Perform remaining multiplies as done for the 2nd order approximation.
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//Result is a scalar.
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MLPPLinAlg alg;
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Ref<MLPPVector> xsc = x->subn(c);
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Ref<MLPPMatrix> mxsc;
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mxsc.instance();
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mxsc->row_add_mlpp_vector(xsc);
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Ref<MLPPMatrix> result_mat = third_order_tensor(function, c)->tensor_vec_mult(xsc);
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real_t result_scalar = mxsc->multn(result_mat->multn(mxsc->transposen()))->element_get(0, 0);
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return quadratic_approximationv(function, c, x) + (1 / 6) * result_scalar;
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}
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real_t MLPPNumericalAnalysis::laplacian(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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Ref<MLPPMatrix> hessian_matrix = hessian(function, x);
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real_t laplacian = 0;
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Size2i hessian_matrix_size = hessian_matrix->size();
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for (int i = 0; i < hessian_matrix_size.y; i++) {
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laplacian += hessian_matrix->element_get(i, i); // homogenous 2nd derivs w.r.t i, then i
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}
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return laplacian;
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}
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String MLPPNumericalAnalysis::second_partial_derivative_test(real_t (*function)(const Ref<MLPPVector> &), const Ref<MLPPVector> &x) {
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MLPPLinAlg alg;
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Ref<MLPPMatrix> hessian_matrix = hessian(function, x);
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Size2i hessian_matrix_size = hessian_matrix->size();
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// The reason we do this is because the 2nd partial derivative test is less conclusive for functions of variables greater than
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// 2, and the calculations specific to the bivariate case are less computationally intensive.
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if (hessian_matrix_size.y == 2) {
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real_t det = hessian_matrix->det();
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real_t secondDerivative = num_diff_2v(function, x, 0, 0);
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if (secondDerivative > 0 && det > 0) {
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return "min";
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} else if (secondDerivative < 0 && det > 0) {
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return "max";
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} else if (det < 0) {
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return "saddle";
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} else {
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return "test was inconclusive";
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}
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} else {
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if (alg.positive_definite_checker(hessian_matrix)) {
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return "min";
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} else if (alg.negative_definite_checker(hessian_matrix)) {
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return "max";
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} else if (!alg.zero_eigenvalue(hessian_matrix)) {
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return "saddle";
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} else {
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return "test was inconclusive";
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}
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}
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}
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void MLPPNumericalAnalysis::_bind_methods() {
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}
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