Except the first assumption that e^x = its own integral, everything else actually makes sense (except the DX are in the wrong powers). You simply treat the "1" and "integral dx" as operators, formally functions from R^R into R^R and "(0)" as calculating the value of the operator on a constant-valued function 0.
EDIT: the step 1/(1-integral) = the limit of a certain series is slightly dubious, but I believe it can be formally proven as well.
EDIT 2: I was proven wrong, read the comments
is it immediately obvious that the inverse of the operator L is 1/L though? Much less the series expansion for the operator...
If you try to fill in the technical details it will be a lot of work compared to a simpler calculus based alternative
But then again some Mathematicians spent the better half of the century formalizing the mathematics used by Physicists like Dirac (spoiler: they all turned out to be valid)
After careful consideration I have come to the conclusion that the inverse of the operator L is obviously not 1/L and you are absolutely right. This derivation is complete nonsense, my apologies. In fact no such inverse can even exist for the operator 1 - integral, as this function is not an injection.
That's the thing about physicists doing math. They know the universe already works. So if they break some math on the way to an explanation, so what? You can fix math. They care about the universe. It's pretty cool sometimes. Like bra-ket notation is really an expression the linear algebra concepts of dual space and adjoints. But to a physicist, it's just how the math should work if it is to do anything useful.
So yeah, this post looks like nonsense. Because it is. But there is a lesson that "math" should work like this, and there is utility in pushing the limits. No pun intended.
Edit: I'm not claiming this is a useful application. It's circular reasoning as this post's parent alludes to.
If you "fill in" the indefinite integral with a (definite integral with) bounds -infinity to x, then I think the first step works. I'm not 100% how to deal with the 1/(1-integral) step, but my guess would be to transform to the Laplace domain because Laplace transform analysis is "aware of" convergence issues, i.e. the region of convergence "pops out" when calculating the transform, or it's present in the lookup table entry.
I don't believe you can just factor our e^x in the second step like that. That seems in incorrect to me. Then again I've been out of calculus for years now.
I think this can be translated into something not completely wrong. I.e. I have seen calculus like this in old-school books that use operational calculus. It usually uses differential operators instead of integrals, although antiderivatives get operational formulas in terms of the differential operator, and it leads to the Laplace transform because it exhibits identical operational properties.
You have no idea. This is tame compared to some of the shit I seen in my masters.
I remember one time we had an exercise where the calculation yielded a violently nonconvergent improper integral.
Now, we had already been introduced to some "tricks" to "deal with" those. And I do mean "tricks" as in magic. Arcane spells best described as "praying to the obscure gods of Borel summation until some incantation accidentally summoned untold horrors that would swallow infinities into fractional dimensions converging to zero" or some bullshit like that.
But this one was so bizarre that the whole class was stumped. Our runes were powerless, what remained of our sanities was fraying and disappearing into the abyss that kept lookingback for more.
Then the TA just tsk'd at our collective weakness, deadass looked into each of our eyeballs and wrote this on the blackboard