This is full of interest, major progress is being made in the study of precession. It would be most interesting to compare these spin connections with those for retrograde precession, which cannot be accounted for in Einsteinian general relativity (EGR). Finally, it would be of great interest to use the spin conenction components as input parameters (e.g. kappa sub X = 1, kappa sub Y = 1; and kappa sub X = 1, kappa sub Y = 100 in units of inverse metres). The idea is to try to match the experimental and theoretical precession as precisely as possible. The simultaneous equations available for forward precession are Eqs. (11), (25) and (26) for forward precession, and Eqs. (11), (20) and (21) for retrograde precession. They are equation sets in X, Y, X dot and Y dot for input parameters kappa sub X and kappa sub Y. For retrograde precession Eq. (12) reduces to Eq. (13). For forward precession there will be an equivalent of Eq. (13). The amazing thing is that the well known lagrangian of special relativity produces forward and retrograde precession. The task now is to match the theory to experiment.
To: EMyrone@aol.com
Sent: 14/05/2017 15:18:18 GMT Daylight Time
Subj: Plot of spin connectionsThe spin connections have been plotted from the Lagrange solution for t, according to
as derived from eqs.(12,14) of note 377(5). The correspondence to X dot and Y dot can clearly be seen, see both figures.
Horst