Picture empty space as gray. It exists, therefore it exists in time. Imagine the gray color is a visualization of the universal field of time that permeates everything that exists, which has a speed of one second per second.

Imagine that the universal speed of time accelerates such that each second is .0000000000000000001 — or one tenth of one quintillionth — of a second faster (shorter) than the last, thus the speed of time is .9999999999999999999 seconds per second, self-referentially.

Imagine this faster time makes the color whiter. This could be equivalent to saying there is universal entropy since an accelerating second equals decreasing mass, using the formula F=MA, and results in emptier, whiter space.

Now, mass is inertia, which is conserved energy, and the energy is conserved in time, so if the speed of time accelerates universally then it causes the speed of time for mass to accelerate. This acceleration of the speed of time for mass is an effect of the universal acceleration of the speed of time, and effects always follow after their causes, they cannot be simultaneous with them. We can now picture each body as a darker gray spot in our lighter gray field because mass lags behind, slightly slower than the universal speed of time. And we can picture this in the quantum universe as a local field that extends infinitely with density falling with distance according to the inverse square law. This is a local field of slightly slowed time for the body, darker at its center where seconds are longer, and extending out in all directions, having continuously lighter-faster seconds with greater distance from the center.

And thus, all mass is compelled to accelerate towards the centers of these local fields of time, to conserve their slower speed of time, which is conserving inertia, conserving rest in time in universally accelerating time. That’s the gravitational field.

If this is gravity, then it results from entropy, which is equivalent to universal acceleration of the speed of time. This predicts cosmological redshift of light because clocks tick much faster when distant light arrives than they did when the light began its journey. Thus, the rate of cosmological redshift might tell us the universal speed of time, or rate of acceleration of seconds per second. If so, then the measured value of the Gravitational Constant (G) might closely predict the rate of cosmological redshift as perhaps within a quintillionth faster than G, measured as change in meters per meter per second.