I think "mathematics is a mechanical process for solving problems without an intuitive grasp of their nature" is a very good definition, with which many professional mathematicians would agree. Sometimes you're surprised by what pops out when you turn the crank. (Witness: every non-trivial probability problem ever)
Einstein's special theory of relativity was mainly an intuitive interpretation of Lorenz's discovery of Maxwell's equations' invariance under Lorenz transformation. The insight "c is constant in every frame of reference", would not have been possible without Lorenz mechanically working out what sort of transformation would leave Maxwell's equations invariant.
Dirac predicted the existence of the positron solely based on a mechanical process of finding out what sort of equation satisfied the symmetries observed in nature.
My point being that many great intellectual advances have been made by people who trusted the process more than themselves, and that's one of the cornerstones of mathematical thinking: trust the process more than yourself.
> I think "mathematics is a mechanical process for solving
> problems without an intuitive grasp of their nature"
> is a very good definition, with which many professional
> mathematicians would agree.
I am astonished.
No professional mathematician of my acquaintance (and there are many, including three winners of the Fields medal) would agree with that. Every professional mathematician I know would say that mathematics is a creative subject requiring insight, intuition, rigorous logic and occasional luck.
Blindly turning handles just doesn't get results - the search space is way too big to chance across stuff regularly unless guided by some feel for what's going on. Listen to Wiles talk about his proof of FLT, or Gowers talk about the process of doing math.
I'm amazed that you make the claim you do, and am intrigued to know what there is in your background that has led you to that conclusion.
For reference, I'm a PhD in Pure Math, have an Erdos number of 2 (of the second type of 3), and regularly meet with groups of professional mathematicians. I don't tell you this to create a "Proof by Authority" argument, but to give you some background as to my personal experience.
When I'm investigating a physical system, doing the mathematics often tells me something qualitatively different from what I was expecting, and I find that my expectations were wrong more often than I screwed up calculations. I don't mean to trivialize what goes into doing the calculations - what I mean is that I'm constantly solving math problems that force me to revise a flawed understanding of a system.
That's what I mean by "mechanical" - I have to remain disciplined and resist the temptation to reason by analogy to something I may not even understand completely.
If you care, I came to applied mathematics via nuclear engineering.
You're not doing math, you're using mathematical tools. Calculations are effectively arithmetic, and that's not doing math any more than typing code is doing programming.
It's a lot more complicated than that, but setting up the equations is the doing of math - solving the equations is just manipulation, and that's using, not doing. The difference is important - conflating the two leads to many misunderstandings.
I don't want to say that doing math is not creative. Far from it. But mathematicians strive to make themselves unemployed. They prove theorems once and for all, so you don't have to for each right triangle why it has this curious properties about the sum of squares.
Eliminating the need for creativity takes a lot of creativity.
Einstein's special theory of relativity was mainly an intuitive interpretation of Lorenz's discovery of Maxwell's equations' invariance under Lorenz transformation. The insight "c is constant in every frame of reference", would not have been possible without Lorenz mechanically working out what sort of transformation would leave Maxwell's equations invariant.
Dirac predicted the existence of the positron solely based on a mechanical process of finding out what sort of equation satisfied the symmetries observed in nature.
My point being that many great intellectual advances have been made by people who trusted the process more than themselves, and that's one of the cornerstones of mathematical thinking: trust the process more than yourself.