#include "Integrator.hh" #include #include #include #include #include #include #define PI 3.141592653589793 #define RAD_PER_DEG (PI/180.0) typedef struct { double pos[2]; double vel[2]; double acc[2]; } BALL; void deriv(BALL *B) { B->acc[0] = -9.81; B->acc[1] = 0; } void IBall_sim( Integrator_type Alg, std::ostream& dataout) { BALL ball; long tick; double sim_time; const double seconds_per_tick = 0.5; const double initial_speed = 50.0; const double initial_angle = 30.0; dataout.width(16); dataout.precision(14); // Initialization tick = 0; sim_time = 0.0; ball.pos[0] = 5.0; ball.pos[1] = 5.0; ball.vel[0] = initial_speed * sin(initial_angle * RAD_PER_DEG); ball.vel[1] = initial_speed * cos(initial_angle * RAD_PER_DEG); Trick::Integrator *I = Trick::getIntegrator( Alg, 4, seconds_per_tick ); do { // Simulation loop sim_time = tick * seconds_per_tick ; do { // Integration Loop I->time = sim_time; deriv( &ball); //printf("TIME: %g\n",sim_time); I->state_in( &ball.pos[0], &ball.pos[1], &ball.vel[0], &ball.vel[1], NULL); //printf("LOAD STATE: %g %g %g %g\n",ball.pos[0], ball.pos[1], ball.vel[0], ball.vel[1]); I->deriv_in( &ball.vel[0], &ball.vel[1], &ball.acc[0], &ball.acc[1], NULL); //printf("LOAD DERIV: %g %g %g %g\n", ball.vel[0], ball.vel[1], ball.acc[0], ball.acc[1]); I->integrate(); I->state_out( &ball.pos[0], &ball.pos[1], &ball.vel[0], &ball.vel[1], NULL); //printf("STATE OUT: %g %g %g %g\n", ball.pos[0], ball.pos[1], ball.vel[0], ball.vel[1]); } while ( I->intermediate_step); dataout << sim_time << " " << ball.pos[0] << " " << ball.pos[1] << std::endl; tick++; } while (ball.pos[0] >= 0.0); delete( I); } int main(int argc, const char* argv[]) { std::ofstream dataout; std::ofstream gplout; char dataout_name[80]; Integrator_type Algorithm ; const char* Algorithm_name; int test_number; gplout.open("IBall.gpl", std::ofstream::out); gplout << "plot \\" << std::endl; for (test_number = 0; test_number < 5 ; test_number++) { // Select test. switch (test_number) { case 0: Algorithm = Euler; Algorithm_name = "Euler"; break; case 1: Algorithm = Runge_Kutta_2; Algorithm_name = "Runge_Kutta_2"; break; case 2: Algorithm = Runge_Kutta_4; Algorithm_name = "Runge_Kutta_4"; break; case 3: Algorithm = Runge_Kutta_Fehlberg_45; Algorithm_name = "Runge_Kutta_Fehlberg_45"; break; case 4: Algorithm = Runge_Kutta_Fehlberg_78; Algorithm_name = "Runge_Kutta_Fehlberg_78"; break; // case 5: // Algorithm = Runge_Kutta_Gill_4; // Algorithm_name = "Runge_Kutta_Gill_4"; // break; default: std::cerr << "Invalid test number." << std::endl; } strcpy (dataout_name, "IBall_"); strcat (dataout_name, Algorithm_name); strcat (dataout_name, ".dat"); dataout.open( dataout_name); IBall_sim( Algorithm, dataout); dataout.close(); if (test_number > 0) { gplout << ", \\" << std::endl; } gplout << "\"" << dataout_name << "\" using 3:2 title \'" << Algorithm_name << "\' with lines"; } gplout.close(); system("gnuplot -persist IBall.gpl"); return (0); }