solveur/src/sl_critere.cpp

#include "gestionversion.h"

#pragma hdrstop

#include "sl_critere.h"
#include "sl_update.h"
#include "sl_op_plastique.h"
#include <math.h>
//---------------------------------------------------------------------------

#pragma package(smart_init)


//---------------------------------------------------------------------------

SL_CRITERE::SL_CRITERE(double sig_y,double eps_z,double n)
  {
  _SIG_Y=sig_y;
  _EPS_ZERO=eps_z;
  _N=n;
  }


SL_CRITERE::~SL_CRITERE()
{

}

//----------------------------------------------------------------------------------
//Cette mÉthode calcul la contrainte équivalente de Hill et avec un choix approprié
//des coeficients de Hill elle peu faire le calcul de la contrainte de Von Mises
//----------------------------------------------------------------------------------
double SL_CRITERE::get_ctr_equiv(double* sig)
  {
  double SIG_VM;
  SIG_VM=sqrt(0.5*((sig[0]-sig[1])*(sig[0]-sig[1])+(sig[0]-sig[2])*(sig[0]-sig[2])+(sig[1]-sig[2])*(sig[1]-sig[2]))+3*((sig[3]*sig[3])+(sig[4]*sig[4])+(sig[5]*sig[5])));
  return SIG_VM;

  }


double SL_CRITERE::get_crit(double* sig_a,double alpha)
 {
 double sig_s=this->get_ecroui(alpha);
 double sig_equi=this->get_ctr_equiv(sig_a);
 double f=sig_equi-sig_s;
 return f;
 }
//--------------------------------------------------------------------------------------

double SL_CRITERE::get_ecroui(double alpha)
{
double sig_s=_SIG_Y*pow((_EPS_ZERO+alpha),_N);
return sig_s;
}


void SL_CRITERE::get_derive_sigma(double* sig,double* df_sigma)
  {

   double S[6];
   double sig_equiv=this->get_ctr_equiv(sig);
   double trace=sig[0]+sig[1]+sig[2];

   for(int i=0;i<6;i++)
    {
    S[i]=sig[i];
    if(i<3)
    S[i]-=1./3*trace;
    }

   if(sig_equiv!=0.0)
     {
     double coef=3./(2*sig_equiv);
       df_sigma[0]=coef*S[0];
       df_sigma[1]=coef*S[1];
       df_sigma[2]=coef*S[2];
       df_sigma[3]=coef*2*S[3];
       df_sigma[4]=coef*2*S[4];
       df_sigma[5]=coef*2*S[5];
     }

  }
//--------------------------------------------------------------------------------------

//--------------------------------------------------------------------------------------
//L'objectif de cette méthode est de calculer les termes mab de la amtrice M
//--------------------------------------------------------------------------------------

double SL_CRITERE::get_mab(double* Sab,const double* dfa,const double* dfb)
  {
  double mab;
  double df[6];
  SL_UPDATE update;
  update.remettre_a_zeros(df,6);
   mab=0.0;

   for(int i=0;i<6;i++)
    {
     for(int j=0;j<6;j++)
       {
      df[i]+=Sab[i*6+j]*dfb[j];
       }
    mab+=dfa[i]*df[i];
    }


  return mab;

  }


//--------------------------------------------------------------------------------------

Revision:	253
Committed:	Tue Jul 13 19:40:46 2010 UTC (14 years, 10 months ago) by francois
File size:	2860 byte(s)
Log Message:	changement de hiearchie et utilisation de ccmake + mise a jour
#	Rev	Content
1	5	#include "gestionversion.h"
2
3		#pragma hdrstop
4
5		#include "sl_critere.h"
6		#include "sl_update.h"
7		#include "sl_op_plastique.h"
8		#include <math.h>
9		//---------------------------------------------------------------------------
10
11		#pragma package(smart_init)
12
13
14		//---------------------------------------------------------------------------
15
16		SL_CRITERE::SL_CRITERE(double sig_y,double eps_z,double n)
17		{
18		_SIG_Y=sig_y;
19		_EPS_ZERO=eps_z;
20		_N=n;
21		}
22
23
24
25		SL_CRITERE::~SL_CRITERE()
26		{
27
28		}
29
30		//----------------------------------------------------------------------------------
31		//Cette mÉthode calcul la contrainte équivalente de Hill et avec un choix approprié
32		//des coeficients de Hill elle peu faire le calcul de la contrainte de Von Mises
33		//----------------------------------------------------------------------------------
34		double SL_CRITERE::get_ctr_equiv(double* sig)
35		{
36		double SIG_VM;
37		SIG_VM=sqrt(0.5((sig[0]-sig[1])(sig[0]-sig[1])+(sig[0]-sig[2])(sig[0]-sig[2])+(sig[1]-sig[2])(sig[1]-sig[2]))+3((sig[3]sig[3])+(sig[4]sig[4])+(sig[5]sig[5])));
38		return SIG_VM;
39
40		}
41
42
43		double SL_CRITERE::get_crit(double* sig_a,double alpha)
44		{
45		double sig_s=this->get_ecroui(alpha);
46		double sig_equi=this->get_ctr_equiv(sig_a);
47		double f=sig_equi-sig_s;
48		return f;
49		}
50		//--------------------------------------------------------------------------------------
51
52		double SL_CRITERE::get_ecroui(double alpha)
53		{
54		double sig_s=_SIG_Y*pow((_EPS_ZERO+alpha),_N);
55		return sig_s;
56		}
57
58
59
60		void SL_CRITERE::get_derive_sigma(double* sig,double* df_sigma)
61		{
62
63		double S[6];
64		double sig_equiv=this->get_ctr_equiv(sig);
65		double trace=sig[0]+sig[1]+sig[2];
66
67		for(int i=0;i<6;i++)
68		{
69		S[i]=sig[i];
70		if(i<3)
71		S[i]-=1./3*trace;
72		}
73
74		if(sig_equiv!=0.0)
75		{
76		double coef=3./(2*sig_equiv);
77		df_sigma[0]=coef*S[0];
78		df_sigma[1]=coef*S[1];
79		df_sigma[2]=coef*S[2];
80		df_sigma[3]=coef2S[3];
81		df_sigma[4]=coef2S[4];
82		df_sigma[5]=coef2S[5];
83		}
84
85		}
86		//--------------------------------------------------------------------------------------
87
88		//--------------------------------------------------------------------------------------
89		//L'objectif de cette méthode est de calculer les termes mab de la amtrice M
90		//--------------------------------------------------------------------------------------
91
92		double SL_CRITERE::get_mab(double* Sab,const double* dfa,const double* dfb)
93		{
94		double mab;
95		double df[6];
96		SL_UPDATE update;
97		update.remettre_a_zeros(df,6);
98		mab=0.0;
99
100		for(int i=0;i<6;i++)
101		{
102		for(int j=0;j<6;j++)
103		{
104		df[i]+=Sab[i6+j]dfb[j];
105		}
106		mab+=dfa[i]*df[i];
107		}
108
109
110		return mab;
111
112		}
113
114
115		//--------------------------------------------------------------------------------------
116