Is a bessel LPF much more than a LPF by your definition too? It maintains constant group delay, while many LPFs do not. Its a special LPF, but it still acts as an LPF.
Those are linear response, those can be represented by math.
Why does a real integrator in a real project in real life have any distinction from a mathematical model of an integrator that does the same thing in math language? A real life LPF of any class/implementation has lots of nonlinearities and other non-ideal factors that need to be accounted for to implement it - this is not special to integrators.
As I stated, real integrator has the non linear part, the switch in order to make it work in a lot of requirements. I gave example in #13. Try representing that with math.
An even greater question for you: Is a shock absorbing system on a car a signal filter? Certain force signal frequencies are attenuated, just not electrically. Filtering is a more broad concept than what you make it out to be, and if you want to make a distinction between engineering and the theory behind engineering, then you can consider mechanical and other practical filters and you are opening yourself to a lot of ambiguity that only confuses things. Filtering is both a physical and mathematical process, and so you can't do the "dirt-n-grit, get your hands dirty, practical is what it boils down to" good ol boys approach to define something that is abstract.
I can respect where you're coming from, and I think this disagreement is more down to philosophy and application than definition. I just think you're fighting a losing battle when so many EE professors and engineers teach and work with integrators in a purely filtering/signal&system approach.