Whitehead developed his theory of gravitation by considering how the
world line of a particle is affected by those of nearby particles. He arrived at an expression for what he called the "potential impetus" of one particle due to another, which modified
Newton's law of universal gravitation by including a time delay for the propagation of gravitational influences. Whitehead's formula for the potential impetus involves the
Minkowski metric, which is used to determine which events are causally related and to calculate how gravitational influences are delayed by distance. The potential impetus calculated by means of the Minkowski metric is then used to compute a physical spacetime metric g_{\mu\nu}, and the motion of a
test particle is given by a
geodesic with respect to the metric g_{\mu\nu}. Unlike the
Einstein field equations, Whitehead's theory is
linear, in that the
superposition of two solutions is again a solution. This implies that Einstein's and Whitehead's theories will generally make different predictions when more than two massive bodies are involved. Following the notation of Chiang and Hamity , introduce a Minkowski spacetime with
metric tensor \eta_{ab}=\mathrm{diag}(1, -1, -1, -1), where the indices a, b run from 0 through 3, and let the masses of a set of gravitating particles be m_a. :The Minkowski arc length of particle A is denoted by \tau_A. Consider an event p with co-ordinates \chi^a. A retarded event p_A with co-ordinates \chi_A^a on the world-line of particle A is defined by the relations (y_A^a = \chi^a - \chi_A^a, y_A^a y_{Aa} = 0, y_A^0 > 0). The unit tangent vector at p_A is \lambda_A^a = (dx_A^a/d\tau_A)p_A. We also need the invariants w_A = y_A^a \lambda_{Aa}. Then, a gravitational tensor potential is defined by ::g_{ab} = \eta_{ab} - h_{ab}, :where ::h_{ab} = 2\sum_A \frac{m_A}{w_A^3} y_{Aa} y_{Ab}. It is the metric g that appears in the geodesic equation. ==Experimental tests==