Distance is defined by points and :
(5.14) |
(5.15) |
The first derivatives of with respect to Cartesian coordinates are:
(5.16) | |||
(5.17) |
Angle is defined by points , , and , and spanned by vectors
and :
(5.18) |
The first derivatives of with respect to Cartesian coordinates are:
(5.19) | |||
(5.20) | |||
(5.21) |
These equations for the derivatives have a numerical instability when the angle goes to 0 or to 180. Presently, the problem is `solved' by testing for the size of the angle; if it is too small, the derivatives are set to 0 in the hope that other restraints will eventually pull the angle towards well behaved regions. Thus, angle restraints of 0 or 180 should not be used in the conjugate gradients or molecular dynamics optimizations.
Dihedral angle is defined by points , , , and ():
(5.22) |
(5.23) |
The first derivatives of with respect to Cartesian coordinates are:
(5.24) |
(5.25) |
(5.26) | |||
(5.27) | |||
(5.28) | |||
(5.29) | |||
(5.30) | |||
(5.31) |
These equations for the derivatives have a numerical instability when the angle goes to 0. Thus, the following set of equations is used instead [van Schaik et al., 1993]:
(5.32) | |||
(5.33) | |||
(5.34) | |||
(5.35) | |||
(5.36) | |||
(5.37) |
The only possible instability in these equations is when the length of the central bond of the dihedral, , goes to 0. In such a case, which should not happen, the derivatives are set to 0. The expressions for an improper dihedral angle, as opposed to a dihedral or dihedral angle, are the same, except that indices are permuted to . In both cases, covalent bonds , , and are defining the angle.
xx
Atomic density for a given atom is simply calculated as the number of atoms within a distance CONTACT_SHELL of that atom. First derivatives are not calculated, and are always returned as 0.
The absolute atomic coordinates , and are available for every point , primarily for use in anchoring points to planes, lines or points. Their first derivatives with respect to Cartesian coordinates are of course simply 0 or 1.