Functional vs Differential Equations? I'm under the impression that a differential equation has locality hardwired into it (which is why we see them more in physics). However, if I wanted to write something non-local I'd use a functional equation. I am aware there are cases where the differential equation has a functional equation form as well.
snaketao0g
Answered question
2022-10-30
Functional vs Differential Equations? Background I'm under the impression that a differential equation has locality hardwired into it (which is why we see them more in physics). However, if I wanted to write something non-local I'd use a functional equation. I am aware there are cases where the differential equation has a functional equation form as well. Question - Is my initial assumption true: "differential equation has locality hardwired into it"? - Is the cardinality of the set of functional equations more than that of the differential equations? - Is there any functional equation which does not have any differential equation equivalent? - Is there any differential equation which does not have any functional equation equivalent? Caveat While different theories of physics have different definitions of locality (for example bell locality in quantum mechanics and micro-causality in QFT) they all agree one cannot send information (non-random message) from point A to point B without a mediator (which is what I mean by locality in the above in the above).
Answer & Explanation
Phillip Fletcher
Beginner2022-10-31Added 21 answers
Step 1 Functional equations include the usual differential equations as a specialized subclass. One of my favorite functional equations is
It is clear that for any integer n is a solution; it is much less clear whether any other solutions exist. This equation has no differential equation equivalent. Differential equations only have locallity built in if you are considering the class of well-posed initial value problems. Boundary value problems do not necessarily exhibit locality (although I guess that is a cheat because the boundary condition itself is a non-local matter). Thus some of the most important equations in physics, including the steady-state Schroedinger equation in spherical or cylindrical coordinates, are non-local when the wave function is considered as a function of the angle about some axis. Step 2 In between functional equations (which when non-trivial are often impossibly difficult to work with) and differential equations (which often can be attacked by perturbation theory, and a host of other cool tools) I offer differential difference equations. For example, for some given initial value curve and som initial velocity value v,
Differential difference equation problems can have many of the same features as ordinary eigenvalue problems, yet can exhibit some of the same headaches as full-blown non-trivial functional equation problems. The cardinality issue is not easy and may be subtle. I believe the cardinality of the set of all differential equations is the same as the cardinality of the functions, but when you expand to functional equations, that may change.