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<blockquote data-quote="alamocity" data-source="post: 174204" data-attributes="member: 10479"><p>The below is a preliminary mass = energy = space-time equation formulated from special relativity (must adjust for hyperbolic space)</p><p></p><p>-[(x^2-y^2) + (y((x+y)(-x+y))^1/2) / (x+y) (x-y)]</p><p></p><p>It shows how space-time folds into many densities; radiating energy, momentum, angular momentum in objects, having characteristics of both particles and waves while being neither one of those.</p><p></p><p>From: Liquid Space Theory</p><p></p><p>F = force</p><p>M = mass initial</p><p>V = velocity</p><p>C = speed of light</p><p>A = acceleration</p><p>H = Planck's constant</p><p>E = energy</p><p></p><p>F = {[(m/ (1-(v^2/c^2)) ^(1/2)]-m}a</p><p></p><p>Second law of time</p><p></p><p>A ={{[(m/ (1-(v^2/c^2)) ^(1/2)]-m}^-1}f</p><p></p><p>Infinite change of time</p><p></p><p>M = [f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a</p><p></p><p>Mass as a vector in a 3- orthogonal space</p><p></p><p>V = c [- (ma/ma-f )^2 +1]^1/2</p><p></p><p>Velocity of time</p><p></p><p>C = [v / [- (ma/ma-f )^2 +1]^1/2</p><p></p><p>Speed of light as a function of mass</p><p></p><p>E = {[f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a}{[v / [- (ma/ma-f )^2 +1]^1/2 }^2</p><p></p><p>Time conservation law</p><p></p><p>Wave = {{[f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a}{[v / [- (ma/ma-f )^2 +1]^1/2 }^2 } / h</p><p></p><p>(e / h)</p><p></p><p>Wave length and energy of the force</p><p>Energy of the force = {{[(m/(1-(v^2/c^2)) ^(1/2)]-m}c^2}</p><p>Wave = {{[(m/ (1-(v^2/c^2)) ^(1/2)]-m}c^2} / h</p><p></p><p></p><p>code: As you travel the currents of time beware of whirlpools you encounter and the damaging counter current. Your life will be right if you follow God and the never-ending fulfillment of his understanding.</p></blockquote><p></p>
[QUOTE="alamocity, post: 174204, member: 10479"] The below is a preliminary mass = energy = space-time equation formulated from special relativity (must adjust for hyperbolic space) -[(x^2-y^2) + (y((x+y)(-x+y))^1/2) / (x+y) (x-y)] It shows how space-time folds into many densities; radiating energy, momentum, angular momentum in objects, having characteristics of both particles and waves while being neither one of those. From: Liquid Space Theory F = force M = mass initial V = velocity C = speed of light A = acceleration H = Planck's constant E = energy F = {[(m/ (1-(v^2/c^2)) ^(1/2)]-m}a Second law of time A ={{[(m/ (1-(v^2/c^2)) ^(1/2)]-m}^-1}f Infinite change of time M = [f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a Mass as a vector in a 3- orthogonal space V = c [- (ma/ma-f )^2 +1]^1/2 Velocity of time C = [v / [- (ma/ma-f )^2 +1]^1/2 Speed of light as a function of mass E = {[f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a}{[v / [- (ma/ma-f )^2 +1]^1/2 }^2 Time conservation law Wave = {{[f /{[(1/ (1-(v^2/c^2)) ^(1/2)]-1}a}{[v / [- (ma/ma-f )^2 +1]^1/2 }^2 } / h (e / h) Wave length and energy of the force Energy of the force = {{[(m/(1-(v^2/c^2)) ^(1/2)]-m}c^2} Wave = {{[(m/ (1-(v^2/c^2)) ^(1/2)]-m}c^2} / h code: As you travel the currents of time beware of whirlpools you encounter and the damaging counter current. Your life will be right if you follow God and the never-ending fulfillment of his understanding. [/QUOTE]
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