anorlunda said:
Higher order derivatives in the Lagrangian would violate locality.
https://en.wikipedia.org/wiki/Principle_of_locality
That’s an interesting statement! But I don’t see how it follows from allowing accelerations in the argument of the Lagrangian?
Anyway, is non-locality even the true issue?
Isn’t the entire classical theory (with universal time, i.e. nonrelativistic)
non-local anyway? (Non-local in the sense that the motion of a particle instantaneously changes the related potentials (i.e. it’s force on other particles) everywhere.)
ZapperZ said:
You seem to have lost track of WHY we solve for these things. We often solve for them because we need to know their dynamics, i.e. how do various information about the system changes over time.
Right... my question is about why acceleration isn’t a free variable in the dynamics? If we know the initial positions and velocities of a system then classical theory can (in principle) calculate the subsequent motion. Why does nature not give freedom in initial acceleration as well?
Vanadium 50 said:
As far as I can tell, the answer to the question "Why do we usually see equations of motion that are only second-order in time derivatives?" is "Because we usually deal with problems with constant acceleration"
With all due respect you are severely misunderstanding. It has NOTHING to do with constant acceleration. I know you know that second order equations lead to more than constant acceleration... just look at any simple example, Hooke’s law for a spring, Newton’s law for gravity... not sure why I need to belabor this point...
Mister T said:
Acceleration is just another name for second time derivative of position.I don't understand your question.
anorlunda said:
I don't understand what you mean by that. If position is a state, aren't its derivatives and integrals also states?
When I say “
state variable“ I specifically mean:
a variable that needs to be specified in order for subsequent motion to determined.
So in classical theory position/velocity are the state variables, and acceleration is not.
As far as I can tell, this aspect of the theory has no deeper connections. It seems to just be an assumption which works. That’s fine and all, I’m just asking if there’s logic behind why acceleration (and higher) need not be a “state variable.”
I really don’t think it is that bizarre of a question but maybe I’m just too inarticulate.
Just to (not) get my point across has been very draining /: