I’m shocked at how bad the industry standard 4-layer signal-top/ground/power/signal-bottom stackup is with this new paradigm of thinking.

Even if the power-plane is solid (unlikely: modern designs often need 2 or 3 power rails, and thus the power-plane is often split)… but if power was a solid reference plane, we still have an issue with signals traversing signal-top to signal-bottom and vice versa. The return-path of signal-top traverses the ground plane, while the return-path of signal-bottom traverses the power-plane.

On a 4-layer stackup, ground-and-power are split by the “core”, often 1mm or ~39 mils. That’s too far apart to have any significant amount of capacitance, so ground-and-power planes are effectively cutoff, meaning the return-paths are poorly defined and will bounce and/or radiate out of your board, looking for a way to return.

This video recommends signal-top/ground/ground/signal-bottom for a reason (and therefore, routing power / not having any power-planes), and has the data / analysis to backup why this is the appropriate stackup. Taking this approach means that 4-layer boards have far less room than we might expect, at least if we’re trying to have good EMI. Not only that, but you’ll need 2 vias whenever you traverse from signal-top to signal-bottom, because the return paths need to travel from ground-top to ground-bottom as well (!!!).

It seems like 4-layer boards are barely usable with this new paradigm of thinking. 2-layer boards are nearly impossible (you need to route lots of grounds/return paths on the top-layer, because the 60mils from top-to-bottom means that the bottom ground-plane is barely usable at all).