#ifndef DDBETA_OOOMODEL2d2_H_ #define DDBETA_OOOMODEL2d2_H_ #define OPT_HEADER #include #include #include #include "vecn.hpp" namespace opt_utilities { template class dbeta2d2 :public model,std::vector,std::string> { private: model,std::vector >* do_clone()const { return new dbeta2d2(*this); } public: dbeta2d2() { this->push_param_info(param_info >("ampl1",1));//0 this->push_param_info(param_info >("r01",1));//1 this->push_param_info(param_info >("x01",100));//2 this->push_param_info(param_info >("y01",100));//3 this->push_param_info(param_info >("theta1",0));//4 this->push_param_info(param_info >("beta1",2./3.));//5 this->push_param_info(param_info >("epsilon1",0));//6 this->push_param_info(param_info >("ampl2",1));//7 this->push_param_info(param_info >("r02",1));//8 this->push_param_info(param_info >("x02",100));//9 this->push_param_info(param_info >("y02",100));//10 this->push_param_info(param_info >("theta2",0));//11 this->push_param_info(param_info >("beta2",2./4.));//12 this->push_param_info(param_info >("epsilon2",0));//13 this->push_param_info(param_info >("bkg",0));//14 } T do_eval(const vecn& xy,const std::vector& param) { T x=xy[0]; T y=xy[1]; T ampl1=get_element(param,0); T r01=get_element(param,1); T x01=get_element(param,2); T y01=get_element(param,3); T theta1=get_element(param,4); T beta1=get_element(param,5); T epsilon1=get_element(param,6); T ampl2=get_element(param,7); T r02=get_element(param,8); T x02=get_element(param,9); T y02=get_element(param,10); T theta2=get_element(param,11); T beta2=get_element(param,12); T epsilon2=get_element(param,13); T bkg=get_element(param,14); T x_new1=(x-x01)*cos(theta1)+(y-y01)*sin(theta1); T y_new1=(y-y01)*cos(theta1)-(x-x01)*sin(theta1); //T r1=sqrt(x_new1*x_new1*(1-epsilon1)*(1-epsilon1) // + y_new1*y_new1); //r1/=(1-epsilon1); T r1_r1=x_new1*x_new1/exp(epsilon1/30)+y_new1*y_new1/exp(-epsilon1/30); T x_new2=(x-x02)*cos(theta2)+(y-y02)*sin(theta2); T y_new2=(y-y02)*cos(theta2)-(x-x02)*sin(theta2); T r2_r2=x_new2*x_new2/exp(epsilon2/30)+y_new2*y_new2/exp(-epsilon2/30); // T r2=sqrt(x_new2*x_new2*(1-epsilon2)*(1-epsilon2) // + y_new2*y_new2); //r2/=(1-epsilon2); return bkg+ampl1*pow(1+(r1_r1/r01/r01),-3*beta1+static_cast(.5)) +ampl2*pow(1+(r2_r2/r02/r02),-3*beta2+static_cast(.5)); } }; } #endif //EOF