OrbitalInfo/src/InclinationInfo.cpp

/***************************************************************************
 *   Copyright (C) 2006 by pamelaprod                                      *
 *   pamelaprod@P1.pamela                                                  *
 *                                                                         *
 *   This program is free software; you can redistribute it and/or modify  *
 *   it under the terms of the GNU General Public License as published by  *
 *   the Free Software Foundation; either version 2 of the License, or     *
 *   (at your option) any later version.                                   *
 *                                                                         *
 *   This program is distributed in the hope that it will be useful,       *
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 *   GNU General Public License for more details.                          *
 *                                                                         *
 *   You should have received a copy of the GNU General Public License     *
 *   along with this program; if not, write to the                         *
 *   Free Software Foundation, Inc.,                                       *
 *   59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.             *
 ***************************************************************************/
#include <InclinationInfo.h>

using namespace std;

// InclinationInfoI()::InclinationInfoI() {
//   //  memset(time,0,6*sizeof(double)); 
//   // memset(quad,0,6*4*sizeof(double));
// };

void InclinationInfoI::fill(TArrayC* data){
  short extIndex = 0;
  short innIndex = 0;
  long tempData = 0;
  for (int i = 0; i < 6; i++){
    extIndex = 20*i;
    time[i] = (((data->At(extIndex) << 24) & 0xFF000000) +
               ((data->At(extIndex + 1) << 16) & 0x00FF0000) + ((data->At(extIndex + 2) << 8) & 0x0000FF00) +
               (data->At(extIndex + 3) & 0x000000FF))/128.0;
    for (int j = 0; j < 4; j++){
      innIndex = extIndex + 4*j;
      tempData = ((data->At(innIndex + 4) << 24) & 0xFF000000) + ((data->At(innIndex + 5) << 16) & 0x00FF0000) + ((data->At(innIndex + 6) << 8) & 0x0000FF00) + (data->At(innIndex + 7) & 0x000000FF);
      if (data->At(innIndex + 4) >> 8) {
        quat[i][j] = (~tempData * -1.0)/1073741824.0;
      } else {
        quat[i][j] = tempData / 1073741824.0;
      }
    }
  }
}

void InclinationInfoI::clear() {
   for(UInt_t i = 0; i < 6; i++){
        time[i]=0;
        for(UInt_t j = 0; j < 4; j++) quat[i][j]=0;
   }
return ;   
}


Quaternions::Quaternions() 
  : InclinationInfoI()
{
}


Quaternions::~Quaternions()
{
}

InclinationInfo::InclinationInfo()
  : TObject()
{
}

InclinationInfo::~InclinationInfo()
{
}

/*Sine::Sine()
  : TObject()
{
}

Sine::~Sine()
{
}*/

short int Sign_1(double_t a, Int_t b){
  if(a>0){b=1;}
  if(a<0){b=-1;}
  else{b=0;}
  return b; 
}


/******************************************************************************************************************/
/******************************************************************************************************************/
//*********************                             ***************************************************************/
//*********************     COORDINATE SYSTEMS      ***************************************************************/
//*********************                             ***************************************************************/
//*****************************************************************************************************************/
//*****************************************************************************************************************/
//
//                                  ZISK
//                                 +
//                                / \       YOSK      ZOSK (Directed by Radius)
//                                 |       _        _.
//                                 |      |\        /|
//                                 |        \      / 
//                                 |         \    /
//                                 |.__..__   \  /
//                Orbit     _._.***|        **.\/_        XOSK (Directed by velocity)
//                        .*       | (X0,Y0,Z0) **--.___|
//                     _**         |        /     *.    /
//                   .*            |       *        *
//                  *        ..****|***.. /  R       * 
//                         .*      |    .*.
//                        .*       |   /  *.
//                        * EARTH  |  /    *                                    YISK
//                        *        | /_ _  _*_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _|
//                        *        /       *                                   /
//                         *      /      .*
//                          *.   /      .*
//                            **/*******
//                             /
//                            /
//                           /
//                          /
//                         /
//                        /
//                      |/
//                      *--
//                  XISK
//
//****************************************************************************************************/
//****************************************************************************************************/

    
void InclinationInfo::TransAngle(Double_t x0, Double_t y0, Double_t z0, Double_t Vx0, Double_t Vy0, Double_t Vz0, Double_t q0, Double_t q1, Double_t q2, Double_t q3){
    
    cout.precision(12);

    double_t a = 360/(2*TMath::Pi());
    
    TMatrixD Xij(3,3);
    Xij(0,0) = 1; Xij(0,1) = 0; Xij(0,2) = 0;
    Xij(1,0) = 0; Xij(1,1) = 0; Xij(1,2) = 1;
    Xij(2,0) = 0; Xij(2,1) = -1; Xij(2,2) = 0;
    
    TMatrixD Zij(3,3);
    Zij(0,0) = 0.0; Zij(0,1) = 0.0; Zij(0,2) = -1.0;
    Zij(1,0) = -1.0; Zij(1,1) = 0.0; Zij(1,2) = 0.0;
    Zij(2,0) = 0.0; Zij(2,1) = 1.0; Zij(2,2) = 0.0;

    TMatrixD Pij(3,3);
    Pij(0,0) = pow(q0,2)+pow(q1,2)-pow(q2,2)-pow(q3,2);
    Pij(0,1) = /*2*(q1*q2+q0*q3);/*/ 2*(q1*q2-q0*q3);
    Pij(0,2) = /*2*(q1*q3-q0*q2);/*/ 2*(q1*q3+q0*q2);
    Pij(1,0) = /*2*(q1*q2-q0*q3);/*/ 2*(q1*q2+q0*q3);
    Pij(1,1) = pow(q0,2)-pow(q1,2)+pow(q2,2)-pow(q3,2);
    Pij(1,2) = /*2*(q2*q3+q0*q1);/*/ 2*(q2*q3-q0*q1);
    Pij(2,0) = /*2*(q1*q3+q0*q2);/*/ 2*(q1*q3-q0*q2);
    Pij(2,1) = /*2*(q2*q3-q0*q1);/*/ 2*(q2*q3+q0*q1);
    Pij(2,2) = pow(q0,2)-pow(q1,2)-pow(q2,2)+pow(q3,2);

    TMatrixD Aij(3,3);

    Double_t C1 = y0*Vz0 - z0*Vy0;
    Double_t C2 = z0*Vx0 - x0*Vz0;
    Double_t C3 = x0*Vy0 - y0*Vx0;
    Double_t C  = sqrt(pow(C1,2) + pow(C2,2) + pow(C3,2));
    Double_t V0 = sqrt(pow(Vx0,2)+pow(Vy0,2) + pow(Vz0,2));
    //    Double_t R0 = sqrt(pow(x0,2)+pow(y0,2) + pow(z0,2));
    Aij(0,0) = Vx0/V0;
    Aij(0,1) = C1/C;
    Aij(0,2) = (Vy0*C3-Vz0*C2)/(V0*C);
    Aij(1,0) = Vy0/V0;
    Aij(1,1) = C2/C;
    Aij(1,2) = (Vz0*C1-Vx0*C3)/(V0*C);
    Aij(2,0) = Vz0/V0;
    Aij(2,1) = C3/C;
    Aij(2,2) = (Vx0*C2-Vy0*C1)/(V0*C);

    TMatrixD Bij(3,3);
    Bij(0,0) = Vx0/V0;
    Bij(1,0) = C1/C;
    Bij(2,0) = (Vy0*C3-Vz0*C2)/(V0*C);
    Bij(0,1) = Vy0/V0;
    Bij(1,1) = C2/C;
    Bij(2,1) = (Vz0*C1-Vx0*C3)/(V0*C);
    Bij(0,2) = Vz0/V0;
    Bij(1,2) = C3/C;
    Bij(2,2) = (Vx0*C2-Vy0*C1)/(V0*C);
/*
    cout<<"Coordinates:"<<endl;
    cout<<x0<<"\t"<<y0<<"\t"<<z0<<"\t"<<Vx0/V0<<"\t"<<Vy0/V0<<"\t"<<Vz0/V0<<endl;

    cout<<"Pij"<<endl;
    cout<<Pij(0,0)<<"\t"<<Pij(0,1)<<"\t"<<Pij(0,2)<<endl;
    cout<<Pij(1,0)<<"\t"<<Pij(1,1)<<"\t"<<Pij(1,2)<<endl;
    cout<<Pij(2,0)<<"\t"<<Pij(2,1)<<"\t"<<Pij(2,2)<<endl;
*/
    //Aij.Invert();
    
    TMatrixD Full_(3,3);
    
    Full_ = Bij*(Pij*Zij);
/*/temprary
    TMatrixD Tmp(3,3);
    Tmp=Pij*Zij;
    
    cout<<"Quaternion matrix (Tmp)"<<endl;
    cout<<Tmp(0,0)<<"\t"<<Tmp(0,1)<<"\t"<<Tmp(0,2)<<endl;
    cout<<Tmp(1,0)<<"\t"<<Tmp(1,1)<<"\t"<<Tmp(1,2)<<endl;
    cout<<Tmp(2,0)<<"\t"<<Tmp(2,1)<<"\t"<<Tmp(2,2)<<endl;

    cout<<"Orientation based on Velocity"<<endl;
    cout<<Aij(0,0)<<"\t"<<Aij(0,1)<<"\t"<<Aij(0,2)<<endl;
    cout<<Aij(1,0)<<"\t"<<Aij(1,1)<<"\t"<<Aij(1,2)<<endl;
    cout<<Aij(2,0)<<"\t"<<Aij(2,1)<<"\t"<<Aij(2,2)<<endl;

    cout<<"Satellite Axis in Velocity Reference frame (Full_):"<<endl;
    cout<<Full_(0,0)<<"\t"<<Full_(0,1)<<"\t"<<Full_(0,2)<<endl;
    cout<<Full_(1,0)<<"\t"<<Full_(1,1)<<"\t"<<Full_(1,2)<<endl;
    cout<<Full_(2,0)<<"\t"<<Full_(2,1)<<"\t"<<Full_(2,2)<<endl;
*/
    Double_t u00 = Full_(0,0);
    Double_t u10 = Full_(1,0);
    Double_t u11 = Full_(1,1);
    Double_t u20 = Full_(2,0);
    Double_t u12 = Full_(1,2);
    
    //Double_t u13 = Full_(0,0);
    //Double_t u23 = -Full_(1,0);
    //Double_t u22 = Full_(1,1);
    //Double_t u33 = Full_(2,0);
    //Double_t u21 = Full_(1,2);
    
    Tangazh = a*atan(-u00/u20);
    Kren = a*atan(u10/sqrt(1 - pow(u10,2)));
    Ryskanie = a*atan(u12/u11);

    //Tangazh = a*atan(-u13/u33);
    //Kren = a*atan(-u23/sqrt(1 - pow(u23,2)));
    //Ryskanie = a*atan(u21/u22);
// end temprary

//10RED CHECK
/*
u10 = tan(Kren*TMath::DegToRad())/sqrt(pow(tan(Kren*TMath::DegToRad()),2)+1);
u11 = -sqrt((1-pow(u10,2))/(1+pow(tan(Ryskanie*TMath::DegToRad()),2)));
u12 = u11*tan(Ryskanie*TMath::DegToRad());
u20 = -sqrt((1-pow(u10,2))/(1+pow(tan(Tangazh*TMath::DegToRad()),2)));
u00 = -u20*tan(Tangazh*TMath::DegToRad());

Double_t aa = 1+pow((u20/u00),2);
Double_t by = 2*u10*u11*u20/pow(u00,2);
Double_t cy = (1+pow(u10/u00,2))*pow(u11,2)-1;
Double_t bz = 2*u10*u12*u20/pow(u00,2);
Double_t cz = (1+pow(u10/u00,2))*pow(u12,2)-1;

Int_t uj = TMath::Sign(1.,Ryskanie)*TMath::Sign(1.,Tangazh);
Double_t u21 = (-by+uj*sqrt(pow(by,2)-4*aa*cy))/(2*aa);
Double_t u21s = -TMath::Sign(1.,Kren)*TMath::Abs(u21);
Double_t u01 = TMath::Sign(1.,Ryskanie)*TMath::Abs((u10*u11+u20*u21)/u00);

Int_t fj=1;
if(TMath::Sign(1.,Tangazh)>0 && TMath::Sign(1.,Ryskanie)>0) fj=-1;

Double_t u22 = (-bz+fj*sqrt(pow(bz,2)-4*aa*cz))/(2*aa);
Double_t u22s = -TMath::Sign(1.,Tangazh)*TMath::Abs(u22);
Double_t u02 = -TMath::Abs((u10*u12+u20*u22)/u00);

TMatrixD Dij(3,3);
Dij(0,0) = u00;  Dij(0,1) = u01;  Dij(0,2) = u02;
Dij(1,0) = u10;  Dij(1,1) = u11;  Dij(1,2) = u12;
Dij(2,0) = u20;  Dij(2,1) = u21s;  Dij(2,2) = u22s;

//cout<<"Dij"<<endl;
//cout<<Dij(0,0)<<"\t"<<Dij(0,1)<<"\t"<<Dij(0,2)<<endl;
//cout<<Dij(1,0)<<"\t"<<Dij(1,1)<<"\t"<<Dij(1,2)<<endl;
//cout<<Dij(2,0)<<"\t"<<Dij(2,1)<<"\t"<<Dij(2,2)<<endl;

//Aij.Invert();
//Zij.Invert();
TMatrixD Shij(3,3);
TMatrixD Usij(3,3);
Usij = (Aij*Dij);
Usij.Invert();
Shij = Zij*Usij;
Shij.Invert();

cout<<"Full_ matrix having got from Euler angles"<<endl;
cout<<Shij(0,0)<<"\t"<<Shij(0,1)<<"\t"<<Shij(0,2)<<endl;
cout<<Shij(1,0)<<"\t"<<Shij(1,1)<<"\t"<<Shij(1,2)<<endl;
cout<<Shij(2,0)<<"\t"<<Shij(2,1)<<"\t"<<Shij(2,2)<<endl;

    cout<<"Bank = "<<Kren<<"\tSPitch = "<<Tangazh<<"\tYaw = "<<Ryskanie<<endl;
    if(TMath::Abs(Kren)>10.0){
//    if(Vz0/V0>0.99){
      Int_t Fer;
      cin>>Fer;
    }

    Full_.Delete();
    Aij.Delete();
    Pij.Delete();
    Zij.Delete();
    Xij.Delete();
    Dij.Delete();
    Shij.Delete();
    Usij.Delete();

// END 10RED CHECK
*/
return ;    
}


void InclinationInfo::Clear(Option_t *t){
  //Int_t gyh = 0;
}


//ClassImp(McmdItem)
ClassImp(InclinationInfoI)
ClassImp(Quaternions)
ClassImp(InclinationInfo)
//ClassImp(Sine)
1	/***************************************************************************
2	* Copyright (C) 2006 by pamelaprod *
3	* pamelaprod@P1.pamela *
4	* *
5	* This program is free software; you can redistribute it and/or modify *
6	* it under the terms of the GNU General Public License as published by *
7	* the Free Software Foundation; either version 2 of the License, or *
8	* (at your option) any later version. *
9	* *
10	* This program is distributed in the hope that it will be useful, *
11	* but WITHOUT ANY WARRANTY; without even the implied warranty of *
12	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
13	* GNU General Public License for more details. *
14	* *
15	* You should have received a copy of the GNU General Public License *
16	* along with this program; if not, write to the *
17	* Free Software Foundation, Inc., *
18	* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
19	***************************************************************************/
20	#include <InclinationInfo.h>
21
22	using namespace std;
23
24	// InclinationInfoI()::InclinationInfoI() {
25	// // memset(time,0,6*sizeof(double));
26	// // memset(quad,0,64sizeof(double));
27	// };
28
29	void InclinationInfoI::fill(TArrayC* data){
30	short extIndex = 0;
31	short innIndex = 0;
32	long tempData = 0;
33	for (int i = 0; i < 6; i++){
34	extIndex = 20*i;
35	time[i] = (((data->At(extIndex) << 24) & 0xFF000000) +
36	((data->At(extIndex + 1) << 16) & 0x00FF0000) + ((data->At(extIndex + 2) << 8) & 0x0000FF00) +
37	(data->At(extIndex + 3) & 0x000000FF))/128.0;
38	for (int j = 0; j < 4; j++){
39	innIndex = extIndex + 4*j;
40	tempData = ((data->At(innIndex + 4) << 24) & 0xFF000000) + ((data->At(innIndex + 5) << 16) & 0x00FF0000) + ((data->At(innIndex + 6) << 8) & 0x0000FF00) + (data->At(innIndex + 7) & 0x000000FF);
41	if (data->At(innIndex + 4) >> 8) {
42	quat[i][j] = (~tempData * -1.0)/1073741824.0;
43	} else {
44	quat[i][j] = tempData / 1073741824.0;
45	}
46	}
47	}
48	}
49
50	void InclinationInfoI::clear() {
51	for(UInt_t i = 0; i < 6; i++){
52	time[i]=0;
53	for(UInt_t j = 0; j < 4; j++) quat[i][j]=0;
54	}
55	return ;
56	}
57
58
59	Quaternions::Quaternions()
60	: InclinationInfoI()
61	{
62	}
63
64
65	Quaternions::~Quaternions()
66	{
67	}
68
69	InclinationInfo::InclinationInfo()
70	: TObject()
71	{
72	}
73
74	InclinationInfo::~InclinationInfo()
75	{
76	}
77
78	/*Sine::Sine()
79	: TObject()
80	{
81	}
82
83	Sine::~Sine()
84	{
85	}*/
86
87	short int Sign_1(double_t a, Int_t b){
88	if(a>0){b=1;}
89	if(a<0){b=-1;}
90	else{b=0;}
91	return b;
92	}
93
94
95	/******************************************************************************************************************/
96	/******************************************************************************************************************/
97	//******************* *************************************************************/
98	//******************* COORDINATE SYSTEMS *************************************************************/
99	//******************* *************************************************************/
100	//*****************************************************************************************************************/
101	//*****************************************************************************************************************/
102	//
103	// ZISK
104	// +
105	// / \ YOSK ZOSK (Directed by Radius)
106	// \| _ _.
107	// \| \|\ /\|
108	// \| \ /
109	// \| \ /
110	// \|.__..__ \ /
111	// Orbit _._.*\| .\/_ XOSK (Directed by velocity)
112	// .* \| (X0,Y0,Z0) **--.___\|
113	// _** \| / *. /
114	// .* \| * *
115	// * ..**\|.. / R
116	// .* \| .*.
117	// .* \| / *.
118	// * EARTH \| / * YISK
119	// * \| /_ _ _*_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _\|
120	// * / * /
121	// * / .*
122	// . / .
123	// /*****
124	// /
125	// /
126	// /
127	// /
128	// /
129	// /
130	// \|/
131	// *--
132	// XISK
133	//
134	//****************************************************************************************************/
135	//****************************************************************************************************/
136
137
138	void InclinationInfo::TransAngle(Double_t x0, Double_t y0, Double_t z0, Double_t Vx0, Double_t Vy0, Double_t Vz0, Double_t q0, Double_t q1, Double_t q2, Double_t q3){
139
140	cout.precision(12);
141
142	double_t a = 360/(2*TMath::Pi());
143
144	TMatrixD Xij(3,3);
145	Xij(0,0) = 1; Xij(0,1) = 0; Xij(0,2) = 0;
146	Xij(1,0) = 0; Xij(1,1) = 0; Xij(1,2) = 1;
147	Xij(2,0) = 0; Xij(2,1) = -1; Xij(2,2) = 0;
148
149	TMatrixD Zij(3,3);
150	Zij(0,0) = 0.0; Zij(0,1) = 0.0; Zij(0,2) = -1.0;
151	Zij(1,0) = -1.0; Zij(1,1) = 0.0; Zij(1,2) = 0.0;
152	Zij(2,0) = 0.0; Zij(2,1) = 1.0; Zij(2,2) = 0.0;
153
154	TMatrixD Pij(3,3);
155	Pij(0,0) = pow(q0,2)+pow(q1,2)-pow(q2,2)-pow(q3,2);
156	Pij(0,1) = /2(q1q2+q0q3);// 2(q1q2-q0q3);
157	Pij(0,2) = /2(q1q3-q0q2);// 2(q1q3+q0q2);
158	Pij(1,0) = /2(q1q2-q0q3);// 2(q1q2+q0q3);
159	Pij(1,1) = pow(q0,2)-pow(q1,2)+pow(q2,2)-pow(q3,2);
160	Pij(1,2) = /2(q2q3+q0q1);// 2(q2q3-q0q1);
161	Pij(2,0) = /2(q1q3+q0q2);// 2(q1q3-q0q2);
162	Pij(2,1) = /2(q2q3-q0q1);// 2(q2q3+q0q1);
163	Pij(2,2) = pow(q0,2)-pow(q1,2)-pow(q2,2)+pow(q3,2);
164
165	TMatrixD Aij(3,3);
166
167	Double_t C1 = y0Vz0 - z0Vy0;
168	Double_t C2 = z0Vx0 - x0Vz0;
169	Double_t C3 = x0Vy0 - y0Vx0;
170	Double_t C = sqrt(pow(C1,2) + pow(C2,2) + pow(C3,2));
171	Double_t V0 = sqrt(pow(Vx0,2)+pow(Vy0,2) + pow(Vz0,2));
172	// Double_t R0 = sqrt(pow(x0,2)+pow(y0,2) + pow(z0,2));
173	Aij(0,0) = Vx0/V0;
174	Aij(0,1) = C1/C;
175	Aij(0,2) = (Vy0C3-Vz0C2)/(V0*C);
176	Aij(1,0) = Vy0/V0;
177	Aij(1,1) = C2/C;
178	Aij(1,2) = (Vz0C1-Vx0C3)/(V0*C);
179	Aij(2,0) = Vz0/V0;
180	Aij(2,1) = C3/C;
181	Aij(2,2) = (Vx0C2-Vy0C1)/(V0*C);
182
183	TMatrixD Bij(3,3);
184	Bij(0,0) = Vx0/V0;
185	Bij(1,0) = C1/C;
186	Bij(2,0) = (Vy0C3-Vz0C2)/(V0*C);
187	Bij(0,1) = Vy0/V0;
188	Bij(1,1) = C2/C;
189	Bij(2,1) = (Vz0C1-Vx0C3)/(V0*C);
190	Bij(0,2) = Vz0/V0;
191	Bij(1,2) = C3/C;
192	Bij(2,2) = (Vx0C2-Vy0C1)/(V0*C);
193	/*
194	cout<<"Coordinates:"<<endl;
195	cout<<x0<<"\t"<<y0<<"\t"<<z0<<"\t"<<Vx0/V0<<"\t"<<Vy0/V0<<"\t"<<Vz0/V0<<endl;
196
197	cout<<"Pij"<<endl;
198	cout<<Pij(0,0)<<"\t"<<Pij(0,1)<<"\t"<<Pij(0,2)<<endl;
199	cout<<Pij(1,0)<<"\t"<<Pij(1,1)<<"\t"<<Pij(1,2)<<endl;
200	cout<<Pij(2,0)<<"\t"<<Pij(2,1)<<"\t"<<Pij(2,2)<<endl;
201	*/
202	//Aij.Invert();
203
204	TMatrixD Full_(3,3);
205
206	Full_ = Bij(PijZij);
207	/*/temprary
208	TMatrixD Tmp(3,3);
209	Tmp=Pij*Zij;
210
211	cout<<"Quaternion matrix (Tmp)"<<endl;
212	cout<<Tmp(0,0)<<"\t"<<Tmp(0,1)<<"\t"<<Tmp(0,2)<<endl;
213	cout<<Tmp(1,0)<<"\t"<<Tmp(1,1)<<"\t"<<Tmp(1,2)<<endl;
214	cout<<Tmp(2,0)<<"\t"<<Tmp(2,1)<<"\t"<<Tmp(2,2)<<endl;
215
216	cout<<"Orientation based on Velocity"<<endl;
217	cout<<Aij(0,0)<<"\t"<<Aij(0,1)<<"\t"<<Aij(0,2)<<endl;
218	cout<<Aij(1,0)<<"\t"<<Aij(1,1)<<"\t"<<Aij(1,2)<<endl;
219	cout<<Aij(2,0)<<"\t"<<Aij(2,1)<<"\t"<<Aij(2,2)<<endl;
220
221	cout<<"Satellite Axis in Velocity Reference frame (Full_):"<<endl;
222	cout<<Full_(0,0)<<"\t"<<Full_(0,1)<<"\t"<<Full_(0,2)<<endl;
223	cout<<Full_(1,0)<<"\t"<<Full_(1,1)<<"\t"<<Full_(1,2)<<endl;
224	cout<<Full_(2,0)<<"\t"<<Full_(2,1)<<"\t"<<Full_(2,2)<<endl;
225	*/
226	Double_t u00 = Full_(0,0);
227	Double_t u10 = Full_(1,0);
228	Double_t u11 = Full_(1,1);
229	Double_t u20 = Full_(2,0);
230	Double_t u12 = Full_(1,2);
231
232	//Double_t u13 = Full_(0,0);
233	//Double_t u23 = -Full_(1,0);
234	//Double_t u22 = Full_(1,1);
235	//Double_t u33 = Full_(2,0);
236	//Double_t u21 = Full_(1,2);
237
238	Tangazh = a*atan(-u00/u20);
239	Kren = a*atan(u10/sqrt(1 - pow(u10,2)));
240	Ryskanie = a*atan(u12/u11);
241
242	//Tangazh = a*atan(-u13/u33);
243	//Kren = a*atan(-u23/sqrt(1 - pow(u23,2)));
244	//Ryskanie = a*atan(u21/u22);
245	// end temprary
246
247	//10RED CHECK
248	/*
249	u10 = tan(KrenTMath::DegToRad())/sqrt(pow(tan(KrenTMath::DegToRad()),2)+1);
250	u11 = -sqrt((1-pow(u10,2))/(1+pow(tan(Ryskanie*TMath::DegToRad()),2)));
251	u12 = u11tan(RyskanieTMath::DegToRad());
252	u20 = -sqrt((1-pow(u10,2))/(1+pow(tan(Tangazh*TMath::DegToRad()),2)));
253	u00 = -u20tan(TangazhTMath::DegToRad());
254
255	Double_t aa = 1+pow((u20/u00),2);
256	Double_t by = 2u10u11*u20/pow(u00,2);
257	Double_t cy = (1+pow(u10/u00,2))*pow(u11,2)-1;
258	Double_t bz = 2u10u12*u20/pow(u00,2);
259	Double_t cz = (1+pow(u10/u00,2))*pow(u12,2)-1;
260
261	Int_t uj = TMath::Sign(1.,Ryskanie)*TMath::Sign(1.,Tangazh);
262	Double_t u21 = (-by+ujsqrt(pow(by,2)-4aacy))/(2aa);
263	Double_t u21s = -TMath::Sign(1.,Kren)*TMath::Abs(u21);
264	Double_t u01 = TMath::Sign(1.,Ryskanie)TMath::Abs((u10u11+u20*u21)/u00);
265
266	Int_t fj=1;
267	if(TMath::Sign(1.,Tangazh)>0 && TMath::Sign(1.,Ryskanie)>0) fj=-1;
268
269	Double_t u22 = (-bz+fjsqrt(pow(bz,2)-4aacz))/(2aa);
270	Double_t u22s = -TMath::Sign(1.,Tangazh)*TMath::Abs(u22);
271	Double_t u02 = -TMath::Abs((u10u12+u20u22)/u00);
272
273	TMatrixD Dij(3,3);
274	Dij(0,0) = u00; Dij(0,1) = u01; Dij(0,2) = u02;
275	Dij(1,0) = u10; Dij(1,1) = u11; Dij(1,2) = u12;
276	Dij(2,0) = u20; Dij(2,1) = u21s; Dij(2,2) = u22s;
277
278	//cout<<"Dij"<<endl;
279	//cout<<Dij(0,0)<<"\t"<<Dij(0,1)<<"\t"<<Dij(0,2)<<endl;
280	//cout<<Dij(1,0)<<"\t"<<Dij(1,1)<<"\t"<<Dij(1,2)<<endl;
281	//cout<<Dij(2,0)<<"\t"<<Dij(2,1)<<"\t"<<Dij(2,2)<<endl;
282
283	//Aij.Invert();
284	//Zij.Invert();
285	TMatrixD Shij(3,3);
286	TMatrixD Usij(3,3);
287	Usij = (Aij*Dij);
288	Usij.Invert();
289	Shij = Zij*Usij;
290	Shij.Invert();
291
292	cout<<"Full_ matrix having got from Euler angles"<<endl;
293	cout<<Shij(0,0)<<"\t"<<Shij(0,1)<<"\t"<<Shij(0,2)<<endl;
294	cout<<Shij(1,0)<<"\t"<<Shij(1,1)<<"\t"<<Shij(1,2)<<endl;
295	cout<<Shij(2,0)<<"\t"<<Shij(2,1)<<"\t"<<Shij(2,2)<<endl;
296
297	cout<<"Bank = "<<Kren<<"\tSPitch = "<<Tangazh<<"\tYaw = "<<Ryskanie<<endl;
298	if(TMath::Abs(Kren)>10.0){
299	// if(Vz0/V0>0.99){
300	Int_t Fer;
301	cin>>Fer;
302	}
303
304	Full_.Delete();
305	Aij.Delete();
306	Pij.Delete();
307	Zij.Delete();
308	Xij.Delete();
309	Dij.Delete();
310	Shij.Delete();
311	Usij.Delete();
312
313	// END 10RED CHECK
314	*/
315	return ;
316	}
317
318
319	void InclinationInfo::Clear(Option_t *t){
320	//Int_t gyh = 0;
321	}
322
323
324	//ClassImp(McmdItem)
325	ClassImp(InclinationInfoI)
326	ClassImp(Quaternions)
327	ClassImp(InclinationInfo)
328	//ClassImp(Sine)