A hypothesis is suggested that the fields associated with macroscopic
bodies, such as classical electromagnetic and gravitational fields,
acceleration field, pressure field, dissipation field, strong interaction field
and weak interaction field, are the manifestations of a single general field.
Using the generalized four-velocity as the four-potential of the general field,
with the help of the principle of least action it is shown that each of these
seven fields contributes linearly to the formation of the total four-force
density. The general field equations, equation of the particles’ motion in this
field, equation for the metric and the system’s energy are determined. It
should be noted that the stress-energy tensor of the general field includes not
only the stress-energy tensors of these seven fields, but also the cross terms
with the products of various field strengths. As a result, the energy and
momentum of the system with several fields can differ from the classical
values, not taking into account such cross terms in the general field energy
and momentum.
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