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Orion1
Jan6-04, 09:39 AM
Mass?

Mass is 4 dimensional:
dr_s = space.radius (m) - 1 dimensional space
dA_s = space.area (m^2) - 2 dimensional space
dV_s = space.volume (m^3) - 3 dimensional space
dA_t = time.area (s^2) - 2 dimensional time

Mass is the amount of force per acceleration: (Newton)
m = \frac{ dF}{da} = \frac{N s^2}{m}

Mass is the force fraction in time area per space dimension.
m = F \frac{ dA_t}{dr_s}

Mass is the amount of density in volume or density in space volume.
m = pV = pdV_s

Mass is the fractional energy amount per space-time areas: (Einstein)
m = \frac{ E}{c^2} = E \left( \frac{ dA_t}{dA_s} \right)

Mass is the per Gravitational fraction in a space volume per time area:
m = \frac{ r_s c^2}{G} = \left( \frac{ dr_s}{G} \right) \left( \frac{ dA_s}{dA_t \right)} = \frac{ }{G} \left( \frac{ dV_s}{dA_t \right)}

Gravitation is the per mass fraction in a space volume per time area:
G = \frac{ }{m} \left( \frac{ dV_s}{dA_t} \right)

Integral:
m^2 = \left( \frac{ E}{c^2} \right) ^2 = \frac{ dr_s E}{G}

Gravitational Energy is the gravitational space fraction in the fractional space-time squared areas:
E_g = dr_s \left( \frac{ c^4}{G} \right) = \frac{ dr_s}{G} \left( \frac{dA_s}{dA_t} \right) ^2

Gravitational Energy and Space-Time Areas and Volumes are space dimension Mass exchangable:
E_g = dr_s (1.210E+44 j*m^-1)