mmmboh said:
So why wouldn't we have this problem when using Lorentz boosts?
I think that's an interesting historical question. The equations for electricity and magnetism, for example, are not the same when you make a Gallileo boost of the form y=x+vt. People tried to save it by introducing an ether fluid, and so when you boost you also have to boost the ether fluid. But ultimately people abandoned the notion that the laws of physics must remain the same under Gallilean boosts, and used Lorentz boosts instead.
So the requirement that the equations must remain the same under a Lorentz transformation greatly restricts what type of forces you can have. Just as you cannot have the equation:
-kx'=mx''
because it violates Gallileo boosts, and instead must modify it by:
-k(x'-u)=mx''
where u is an ether, requiring that the equations must be the same under Lorentz transformation eliminates many possible forces that people can conjure up.
In fact, it's even more than that. Requiring that the equations remain the same under Lorentz transformation actually restricts what type of particles you can have. There are only a couple of types: scalar particles, vector particles, tensor particles, spinor particles, and mixed tensor/spinor particles. So if you want to invent a new type of mathematical object to describe a particle instead of a vector or spinor, then it's actually very hard to do because Lorentz transformation takes away a lot of your freedom: you would have to find a new representation of the Lorentz group besides spinors and vectors, in the jargon of particle physics.