10 gpp is a pretty standard method of measuring bow performance. It's not about the absolute amount of energy transferred, its about the amount relative to the stored energy: efficiency. Shooting heavier arrows will reduce the difference between both bows, but will not remove it entirely (unless shooting extremely heavy arrows). Shooting lighter arrows will likely exacerbate the difference. But I don't have lighter arrows than 163 gr.
But it seems many are missing the point: FD-curves fool the arm, not the arrow. I don't see anyone commenting on the core of the matter. Everyone is trying to find a way out of what seems to be an uncomfortable situation.
Joachim, I wasn't trying to find a way out of an uncomfortable situation and I accept (and already agreed) that F/D curves don't necessarily represent what the arrow sees. I know 10 gpp is the usual standard comparison, and a dowel painted black can serve as a lighter "arrow" as far as a Chrony is concerned. I'm sure you have access to heavier arrows, and they don't have to be tremendously so. I was just curious if there would be a difference, and just how much difference there was. Of course you don't have to try them if you don't want. It was just a request.
As far as commenting on the core of the matter, here it is:
The string can only deliver to an arrow as much energy as that arrow RESISTS while moving. The resistance an arrow presents to the string takes two forms: inertia, and friction.
Ignoring friction, inertia is a result of mass -- the arrow's weight, in other words. A heavier arrow accelerates more slowly and absorbs more of the available energy.
A very light arrow has little inertia. That's a plus as far as speed goes. It can accelerate very quickly immediately after the string is released.
If a bow has very slow limbs / heavy tips, high stack, high internal resistance and a high draw weight, it may be possible for a light arrow to outrun the limbs (and string) soon after release. If so, it is gaining no energy at that point. No matter what the F/D curve says is the draw weight at that distance (and further along) before it leaves the bow. In fact, if the arrow nock is tight, it may actually be dragging the string with it.
A heavier arrow, accelerating slower, may absorb energy from release all the way to brace height, since it is not moving as fast as the limbs and string. It is also resisting the string more because of its inertia. It is technically a more efficient system, and its behavior will look a little more like the F/D curve, although it will never receive the forces that the F/D curve shows.
If those are extreme cases, it's also possible to imagine cases in between, where a light arrow receives a smaller fraction of the energy available than the heavier arrow from a somewhat faster bow, but where the differences are less extreme.
Since a light arrow mainly gets its energy from the furthest part of the draw, the difference in these classes of tip designs can favor (or not) that segment of the release cycle. So also can tip mass, and a whole lot of other variables. I personally think it would be very difficult to isolate all of the factors which contribute to initial limb tip speed.
In fact, testing arrows of different weights might be a very useful measure of whether a bow is slinging an arrrow for most of the draw length or only the initial part, and at what weight arror this transition occurs. And that is why I was just curious about the results using different arrows. Nothing personal, nor trying to prove anyone right or wrong.
