Jim,
Gravity has to be dynamic, like other forces, otherwise objects wouldn't stay in orbit around each other as they moved. For example, the moon wouldn't stay in orbit around the earth as the earth orbited around the sun, unless the earth's gravity somehow moves with the earth.
So, if the attraction has to move with the source, that begs the question of exactly how in detail it moves. Usually, in physics, it takes time for effects to propagate. Its very well supported by observation that all electromagnetic long-range effects propagate with the speed of light. There is much less measured with respect to gravitational effects, because the measurements are more difficult. Personally, I don't at the moment understand the equations of general relativity (the most widely-accepted theory of gravity) well enough to have an opinion based on them about how fast either the gravitational force or gravitational radiation propagate. However, if it were analagous to electromagnetism in this area (as Prof Steven Carlip asserts per one of the links above), I am confident that a time-advanced force component would be generally considered much more plausible than an instantaneous effect.
As Feynman points out in his speech I linked to, the time-advanced parts are actually in the theory and generally ignored, rather than being an unnecessary addition.
Also, these would certainly not cancel tidal forces in general, to the extent that tidal forces are due to the variation of gravitational attraction with range effect on extended bodies. That is, the water on the side of the earth towards the moon is more attracted to the moon than the water on the far side. This is the m ain cause of a tidal budge, though probably not the complete story, but that is beyond my present ken. The range variation is still true under my hypothesis, just as it is under TVF's of instantaneous propagation.
I would agree that it should be assessed quantitatively what if any are the differences in observable effects of retarded versus instantaneous versus retarded plus advanced force. This assessment has to be done with a full mathematical formalism rather than just with hand-wavy arguments. I am not yet convinced that there is anything wrong with the current consensus that gravity effects are retarded at the speed of light, although I do find the hand-wavy argument very convincing. Until one can fully understand arguments to the contrary from such as Carlip, I would think it would be rash to dismiss them out of hand. However, if these arguments are flawed, and propagation delays do cause forces to become non-central, then restoring centrality via time-advanced effects would seem to me at least equally plausible as instantaneous propagation. So it would come down to what are the differences in observable effects in the two theories.
So far I have had two possible differences suggested. One above is tidal forces, but I can definitely argue that tidal forces are preserved under my proposal and I would think they would be more similar to the instantaneous-propagation model than to the retarded-only-force model. If somebody can explain how they would be different I would be fascinated to hear it.
The other proposed discriminant was suggested to me by TVF in an email, that as described in his speed-of-gravity paper there are measurements that show the gravity vector from earth points to the present position of the sun rather than the past position where light comes from. That contradicts the hand-wavy model of retarded effects but is equally consistent with instantaneous and hand-wavy retarded plus advanced forces. Carlip, however, says it does not actually contradict a rigorous treatment in GR with presumably retarded-only forces.
It will be interesting to see how this plays out but it will take a while. I do intend to build a model of the process using GR. Actually I already have one that implements retarded-potential electromagnetic forces and I intend to put Carlip's assertions about that to the test of simulation.
