So let us put some perspective on
my version of Richard Gill's S^2 version of Michel Fodje's original simulation of my
3-sphere, or SU(2), model for the EPR-Bohm correlation.
As we can see from the details discussed in the above paper, my analytical model predicts the (negative) cosine correlation
exactly. What is more, in Bell's local-realistic framework (discussed in his 1964 paper) we are completely free to choose whatever initial or complete state of the system we like. In the present representation of the 3-sphere this initial state is represented by the pair (
e_o, theta_o), which are simply four numbers. These numbers depend on the system under consideration. They depend on the symmetry of the physical situation. For example, for the GHZ or Hardy case the initial state would be nothing like these four numbers.
Now have a look at the
derivation of this state within my 3-sphere model. As we can see from just above the box of eq.(10), I had made a simple choice for the initial state by choosing the function f(theta_o) defined in eq.(7). This choice simply specifies the magnitude of the sum of the two initial quaternions,
p_o and
q_o, and thereby also specifies the initial state (
e_o, theta_o). In Michel Fodje's simulation the choice I made for f(theta_o) seemed necessary and sufficient to produce the correct correlation. It now appears that when one zooms-in with greater precision, the initial state is in fact what has now been chosen in the latest simulation.
I am grateful to Richard Gill for insisting on greater precision for the simulation, which helped me discover a more accurate choice for the initial state (
e_o, theta_o) in the EPR-Bohm case. I am also grateful to Chantal Roth for encouraging me to learn R and thus investigate Richard Gill's simulation myself. The result of my investigations is
not devoid of beauty.
So let us put some perspective on [url=http://rpubs.com/chenopodium/joychristian]my version[/url] of Richard Gill's S^2 version of Michel Fodje's original simulation of my [url=http://libertesphilosophica.info/blog/wp-content/uploads/2014/01/Book-Chapter.pdf]3-sphere, or SU(2), model[/url] for the EPR-Bohm correlation.
As we can see from the details discussed in the above paper, my analytical model predicts the (negative) cosine correlation [b]exactly[/b]. What is more, in Bell's local-realistic framework (discussed in his 1964 paper) we are completely free to choose whatever initial or complete state of the system we like. In the present representation of the 3-sphere this initial state is represented by the pair ([b]e[/b]_o, theta_o), which are simply four numbers. These numbers depend on the system under consideration. They depend on the symmetry of the physical situation. For example, for the GHZ or Hardy case the initial state would be nothing like these four numbers.
Now have a look at the [url=http://libertesphilosophica.info/blog/wp-content/uploads/2014/02/complete.pdf]derivation of this state[/url] within my 3-sphere model. As we can see from just above the box of eq.(10), I had made a simple choice for the initial state by choosing the function f(theta_o) defined in eq.(7). This choice simply specifies the magnitude of the sum of the two initial quaternions, [b]p[/b]_o and [b]q[/b]_o, and thereby also specifies the initial state ([b]e[/b]_o, theta_o). In Michel Fodje's simulation the choice I made for f(theta_o) seemed necessary and sufficient to produce the correct correlation. It now appears that when one zooms-in with greater precision, the initial state is in fact what has now been chosen in the latest simulation.
I am grateful to Richard Gill for insisting on greater precision for the simulation, which helped me discover a more accurate choice for the initial state ([b]e[/b]_o, theta_o) in the EPR-Bohm case. I am also grateful to Chantal Roth for encouraging me to learn R and thus investigate Richard Gill's simulation myself. The result of my investigations is [url=http://rpubs.com/chenopodium/joychristian]not devoid of beauty[/url].
