where \(x=x_g=x_c=x_T\), all space dimensions are taken to be equivalent and the velocity of the particles along their respective dimensions is \(c\), not necessarily light speed.
We see that \(a_\psi\) is then the radius of the circular path perpendicular to the time axis,
\(r=a_\psi\)
as such \(r\) is increased by increasing, \(a_\psi\). In the case of a sonic cone at 7.489 Hz, from the post "All Of Max", the equivalent of the third Maxwell's Equations,
\(\oint_{2\pi a_\psi} { E_{ \psi } } \, d\, \lambda =-\cfrac{1}{c^2} \cfrac{d}{d\,t}\left\{\oint _{\pi a^2_{\psi}}{ F_{ \psi } } dA_{ l }\right\}=-\cfrac{1}{c^2} \cfrac{d\,\Psi}{d\,t}\) --- (1)
where a change in flux through an area \(A_l\) induces \(E_\psi\) around a loop \(2\pi a_\psi\). When \(F_\psi\) is increased at a constant rate, both \(E_\psi\) and \(a_\psi\) are decrease until the equation is satisfied. Similarly, when \(F_\psi\) is decreased at a constant rate, both \(E_\psi\) and \(a_\psi\) are increase until the equation is satisfied. \(F_\psi\) is set to resonate with Earth gravitational field of 7.489 Hz.
From the post "Cold Jump",
\(\Delta_t=\cfrac{\partial\,t_{gf}}{\partial\,t}-\cfrac{\partial\,t_{gi}}{\partial\,t}=\cfrac{1}{mc^2}(\cfrac{\partial\,t_{gi}}{\partial\,t}E_{\Delta h}+t_{gi}\cfrac{\partial\,E_{\Delta h}}{\partial\,t})\)
changing \(E_{\Delta h}\) results in a time differential \(\Delta_t\). \(E_{\Delta h}\) is the result of a change in \(a_\psi\) as a rate of change in \(\Psi\) is applied. The negative sign in expression (1), suggests an opposing change to the driving force \(\Psi\).
As \(\Psi\) is increased,
\(\Psi_{\partial\,t}\gt0\)
\(\Delta_t\lt0\) and we are back in time.
As \(\Psi\) is decreased,
\(\Psi_{\partial\,t}\lt0\)
\(\Delta_t\gt0\) and we move forward in time.
To go forward in time, \(\Psi\) is set to resonate to a high value slowly and then dropped suddenly. To return, \(\Psi\) is set to resonate to a high value instantly; multiple hops might be necessary to travel to the past.
Don't panic. Just consistent science fiction.
Don't panic. Just consistent science fiction.
