mdtools/md_code/DirectionalAtom.cpp

#include <cmath>

#include "Atom.hpp"

void DirectionalAtom::setA( double the_A[3][3] ){
  
  Axx = the_A[0][0]; Axy = the_A[0][1]; Axz = the_A[0][2];
  Ayx = the_A[1][0]; Ayy = the_A[1][1]; Ayz = the_A[1][2];
  Azx = the_A[2][0]; Azy = the_A[2][1]; Azz = the_A[2][2];
}

void DirectionalAtom::setI( double the_I[3][3] ){
  
  Ixx = the_I[0][0]; Ixy = the_I[0][1]; Ixz = the_I[0][2];
  Iyx = the_I[1][0]; Iyy = the_I[1][1]; Iyz = the_I[1][2];
  Izx = the_I[2][0]; Izy = the_I[2][1]; Izz = the_I[2][2];
}

void DirectionalAtom::setQ( double the_q[4] ){

  double q0Sqr, q1Sqr, q2Sqr, q3Sqr;

  q0Sqr = the_q[0] * the_q[0];
  q1Sqr = the_q[1] * the_q[1];
  q2Sqr = the_q[2] * the_q[2];
  q3Sqr = the_q[3] * the_q[3];
  

  Axx = q0Sqr + q1Sqr - q2Sqr - q3Sqr;
  Axy = 2.0 * ( the_q[1] * the_q[2] + the_q[0] * the_q[3] );
  Axz = 2.0 * ( the_q[1] * the_q[3] - the_q[0] * the_q[2] );
  
  Ayx = 2.0 * ( the_q[1] * the_q[2] - the_q[0] * the_q[3] );
  Ayy = q0Sqr - q1Sqr + q2Sqr - q3Sqr;
  Ayz = 2.0 * ( the_q[2] * the_q[3] + the_q[0] * the_q[1] );

  Azx = 2.0 * ( the_q[1] * the_q[3] + the_q[0] * the_q[2] );
  Azy = 2.0 * ( the_q[2] * the_q[3] - the_q[0] * the_q[1] );
  Azz = q0Sqr - q1Sqr -q2Sqr +q3Sqr;
}

void DirectionalAtom::getU( double the_u[3] ){
  
  the_u[0] = sux;
  the_u[1] = suy;
  the_u[2] = suz;

  this->body2Lab( the_u );
}

void DirectionalAtom::getQ( double q[4] ){
  
  double t, s;
  double ad1, ad2, ad3;

  t = Axx + Ayy + Azz + 1.0;
  if( t > 0.0 ){
    
    s = 0.5 / sqrt( t );
    q[0] = 0.25 / s;
    q[1] = (Ayz - Azy) * s;
    q[2] = (Azx - Axz) * s;
    q[3] = (Axy - Ayx) * s;
  }
  else{
    
    ad1 = fabs( Axx );
    ad2 = fabs( Ayy );
    ad3 = fabs( Azz );

    if( ad1 >= ad2 && ad1 >= ad3 ){
      
      s = 2.0 * sqrt( 1.0 + Axx - Ayy - Azz );
      q[0] = (Ayz + Azy) / s;
      q[1] = 0.5 / s;
      q[2] = (Axy + Ayx) / s;
      q[3] = (Axz + Azx) / s;
    }
    else if( ad2 >= ad1 && ad2 >= ad3 ){

      s = sqrt( 1.0 + Ayy - Axx - Azz ) * 2.0;
      q[0] = (Axz + Azx) / s;
      q[1] = (Axy + Ayx) / s;
      q[2] = 0.5 / s;
      q[3] = (Ayz + Azy) / s;
    }
    else{
      
      s = sqrt( 1.0 + Azz - Axx - Ayy ) * 2.0;
      q[0] = (Axy + Ayx) / s;
      q[1] = (Axz + Azx) / s;
      q[2] = (Ayz + Azy) / s;
      q[3] = 0.5 / s;
    }
  }
}


void DirectionalAtom::setEuler( double phi, double theta, double psi ){
  
  Axx = (cos(phi) * cos(psi)) - (sin(phi) * cos(theta) * sin(psi));
  Axy = (sin(phi) * cos(psi)) + (cos(phi) * cos(theta) * sin(psi));
  Axz = sin(theta) * sin(psi);
  
  Ayx = -(cos(phi) * sin(psi)) - (sin(phi) * cos(theta) * cos(psi));
  Ayy = -(sin(phi) * sin(psi)) + (cos(phi) * cos(theta) * cos(psi));
  Ayz = sin(theta) * cos(psi);

  Azx = sin(phi) * sin(theta);
  Azy = -cos(phi) * sin(theta);
  Azz = cos(theta);
}


void DirectionalAtom::lab2Body( double r[3] ){

  double rl[3]; // the lab frame vector 
  
  rl[0] = r[0];
  rl[1] = r[1];
  rl[2] = r[2];

  r[0] = (Axx * rl[0]) + (Axy * rl[1]) + (Axz * rl[2]);
  r[1] = (Ayx * rl[0]) + (Ayy * rl[1]) + (Ayz * rl[2]);
  r[2] = (Azx * rl[0]) + (Azy * rl[1]) + (Azz * rl[2]);
}

void DirectionalAtom::body2Lab( double r[3] ){

  double rb[3]; // the body frame vector 
  
  rb[0] = r[0];
  rb[1] = r[1];
  rb[2] = r[2];

  r[0] = (Axx * rb[0]) + (Ayx * rb[1]) + (Azx * rb[2]);
  r[1] = (Axy * rb[0]) + (Ayy * rb[1]) + (Azy * rb[2]);
  r[2] = (Axz * rb[0]) + (Ayz * rb[1]) + (Azz * rb[2]);
}

Revision:	10
Committed:	Tue Jul 9 18:40:59 2002 UTC (22 years ago) by mmeineke
Original Path:	*branches/mmeineke/mdtools/md_code/DirectionalAtom.cpp*
File size:	3428 byte(s)
Log Message:	everything you need to make libmdtools
#	Content
1	#include <cmath>
2
3	#include "Atom.hpp"
4
5	void DirectionalAtom::setA( double the_A[3][3] ){
6
7	Axx = the_A[0][0]; Axy = the_A[0][1]; Axz = the_A[0][2];
8	Ayx = the_A[1][0]; Ayy = the_A[1][1]; Ayz = the_A[1][2];
9	Azx = the_A[2][0]; Azy = the_A[2][1]; Azz = the_A[2][2];
10	}
11
12	void DirectionalAtom::setI( double the_I[3][3] ){
13
14	Ixx = the_I[0][0]; Ixy = the_I[0][1]; Ixz = the_I[0][2];
15	Iyx = the_I[1][0]; Iyy = the_I[1][1]; Iyz = the_I[1][2];
16	Izx = the_I[2][0]; Izy = the_I[2][1]; Izz = the_I[2][2];
17	}
18
19	void DirectionalAtom::setQ( double the_q[4] ){
20
21	double q0Sqr, q1Sqr, q2Sqr, q3Sqr;
22
23	q0Sqr = the_q[0] * the_q[0];
24	q1Sqr = the_q[1] * the_q[1];
25	q2Sqr = the_q[2] * the_q[2];
26	q3Sqr = the_q[3] * the_q[3];
27
28
29	Axx = q0Sqr + q1Sqr - q2Sqr - q3Sqr;
30	Axy = 2.0 * ( the_q[1] * the_q[2] + the_q[0] * the_q[3] );
31	Axz = 2.0 * ( the_q[1] * the_q[3] - the_q[0] * the_q[2] );
32
33	Ayx = 2.0 * ( the_q[1] * the_q[2] - the_q[0] * the_q[3] );
34	Ayy = q0Sqr - q1Sqr + q2Sqr - q3Sqr;
35	Ayz = 2.0 * ( the_q[2] * the_q[3] + the_q[0] * the_q[1] );
36
37	Azx = 2.0 * ( the_q[1] * the_q[3] + the_q[0] * the_q[2] );
38	Azy = 2.0 * ( the_q[2] * the_q[3] - the_q[0] * the_q[1] );
39	Azz = q0Sqr - q1Sqr -q2Sqr +q3Sqr;
40	}
41
42	void DirectionalAtom::getU( double the_u[3] ){
43
44	the_u[0] = sux;
45	the_u[1] = suy;
46	the_u[2] = suz;
47
48	this->body2Lab( the_u );
49	}
50
51	void DirectionalAtom::getQ( double q[4] ){
52
53	double t, s;
54	double ad1, ad2, ad3;
55
56	t = Axx + Ayy + Azz + 1.0;
57	if( t > 0.0 ){
58
59	s = 0.5 / sqrt( t );
60	q[0] = 0.25 / s;
61	q[1] = (Ayz - Azy) * s;
62	q[2] = (Azx - Axz) * s;
63	q[3] = (Axy - Ayx) * s;
64	}
65	else{
66
67	ad1 = fabs( Axx );
68	ad2 = fabs( Ayy );
69	ad3 = fabs( Azz );
70
71	if( ad1 >= ad2 && ad1 >= ad3 ){
72
73	s = 2.0 * sqrt( 1.0 + Axx - Ayy - Azz );
74	q[0] = (Ayz + Azy) / s;
75	q[1] = 0.5 / s;
76	q[2] = (Axy + Ayx) / s;
77	q[3] = (Axz + Azx) / s;
78	}
79	else if( ad2 >= ad1 && ad2 >= ad3 ){
80
81	s = sqrt( 1.0 + Ayy - Axx - Azz ) * 2.0;
82	q[0] = (Axz + Azx) / s;
83	q[1] = (Axy + Ayx) / s;
84	q[2] = 0.5 / s;
85	q[3] = (Ayz + Azy) / s;
86	}
87	else{
88
89	s = sqrt( 1.0 + Azz - Axx - Ayy ) * 2.0;
90	q[0] = (Axy + Ayx) / s;
91	q[1] = (Axz + Azx) / s;
92	q[2] = (Ayz + Azy) / s;
93	q[3] = 0.5 / s;
94	}
95	}
96	}
97
98
99	void DirectionalAtom::setEuler( double phi, double theta, double psi ){
100
101	Axx = (cos(phi) * cos(psi)) - (sin(phi) * cos(theta) * sin(psi));
102	Axy = (sin(phi) * cos(psi)) + (cos(phi) * cos(theta) * sin(psi));
103	Axz = sin(theta) * sin(psi);
104
105	Ayx = -(cos(phi) * sin(psi)) - (sin(phi) * cos(theta) * cos(psi));
106	Ayy = -(sin(phi) * sin(psi)) + (cos(phi) * cos(theta) * cos(psi));
107	Ayz = sin(theta) * cos(psi);
108
109	Azx = sin(phi) * sin(theta);
110	Azy = -cos(phi) * sin(theta);
111	Azz = cos(theta);
112	}
113
114
115	void DirectionalAtom::lab2Body( double r[3] ){
116
117	double rl[3]; // the lab frame vector
118
119	rl[0] = r[0];
120	rl[1] = r[1];
121	rl[2] = r[2];
122
123	r[0] = (Axx * rl[0]) + (Axy * rl[1]) + (Axz * rl[2]);
124	r[1] = (Ayx * rl[0]) + (Ayy * rl[1]) + (Ayz * rl[2]);
125	r[2] = (Azx * rl[0]) + (Azy * rl[1]) + (Azz * rl[2]);
126	}
127
128	void DirectionalAtom::body2Lab( double r[3] ){
129
130	double rb[3]; // the body frame vector
131
132	rb[0] = r[0];
133	rb[1] = r[1];
134	rb[2] = r[2];
135
136	r[0] = (Axx * rb[0]) + (Ayx * rb[1]) + (Azx * rb[2]);
137	r[1] = (Axy * rb[0]) + (Ayy * rb[1]) + (Azy * rb[2]);
138	r[2] = (Axz * rb[0]) + (Ayz * rb[1]) + (Azz * rb[2]);
139	}
140