Math Hierarchy: Fundamentals, Axioms & Exponentiation

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Discussion Overview

The discussion explores the foundational structure of mathematics, particularly focusing on the hierarchy of mathematical concepts, the role of set theory, and the nature of definitions in mathematics, including exponentiation. It touches on theoretical aspects and the relationships between different mathematical frameworks.

Discussion Character

  • Debate/contested
  • Conceptual clarification
  • Exploratory

Main Points Raised

  • Some participants propose that set theory is a fundamental starting point for mathematics, while others argue that other frameworks, such as group theory, can also serve as foundational.
  • One participant suggests that mathematical logic, which includes set theory, could be considered a fundamental area of mathematics.
  • There is a discussion about the interdependence of mathematical concepts, where functions can be defined in terms of sets and vice versa, indicating a lack of a strict hierarchy.
  • Some participants express skepticism about the existence of a natural hierarchy in mathematics, emphasizing the interconnectedness of various mathematical structures.
  • Concerns are raised about the motivations behind different mathematical approaches, questioning whether some methods are chosen based on real-world applications or purely abstract reasoning.
  • There is a mention of the idea that if two mathematical approaches are logically equivalent, the choice of which to use may depend on personal preference or convenience.
  • One participant notes that while Zermelo-Fraenkel set theory with the Axiom of Choice (ZFC) is often seen as a standard, it is ultimately a convention rather than a universally accepted structure of mathematics.

Areas of Agreement / Disagreement

Participants express differing views on the foundational hierarchy of mathematics, with no consensus on whether set theory or other frameworks should be considered more fundamental. The discussion remains unresolved regarding the motivations behind different mathematical approaches and the nature of mathematical conventions.

Contextual Notes

Participants highlight the complexity and interconnections within mathematics, suggesting that definitions and foundational concepts may depend on context and personal preference. The discussion reflects varying opinions on the role of conventions in defining mathematical structures.

Nick R
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If one were to do a bottom up study of math how would it go?

Set theory
.
.
.
?

Is set theory the most fundamental, or does it build on the axioms of some other ideas?

Also, in what section of mathematics is the concept of vectors established? What about "euclidean space" or "other space" established?

Are things like exponentiation arbitrarily defined or is there something more to it that is developed somewhere?
 
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I would say mathematical logic, a subfield of which is set theory.
 
Nick R said:
If one were to do a bottom up study of math how would it go?

Like a roly poly, logic curls up into a ball when you poke at it. You end up with a handful of mathematical objects which can each be defined in terms of the other. Functions are just sets in set theory. But you could just as easily to define sets in terms of functions functions (category theory does something similar to this).

In first-order logic, OR can be defined in terms of NOT and AND. AND can be defined in terms of NOT and OR. NOT can be defined in terms of IMPLICATION and FALSE.

Any Turing-complete system (ie: a computer or any sufficiently powerful logic) is isomorphic to any other.

For bread and butter math, naive set is good enough, as long as you don't poke at it.
 
There is no such hierarchy. Yes, you can start with "sets" and build up mathematics from that. But you can also start with other things, such as, say, group theory, defining the objects in some abstract manner (when you have a set of objects with operations defined on them, it is always possible to define the operations first and then take the objects as "given" by the operations) and then derive set theory from that. There are simply too many interconnections between mathematics to set up any "natural" hierarchy.
 
So basically, the only way a "bottom up" hierarchy exists is if you personally think there is an approach that is more "well motivated" by real/physical examples...

Is it sometimes true that, people concerned with "pure mathematics" may often choose an approach to things that is completely unmotivated by real examples, suggesting that this approach is representative of "what's really going on" even though the motivated approach and the unmotivated approach are logically identical, and the former just makes more sense?
 
Nick R said:
So basically, the only way a "bottom up" hierarchy exists is if you personally think there is an approach that is more "well motivated" by real/physical examples...
People don't think of it as a bottom up hierarchy. If you've already shown that (1) and (2) are equivalent then you can just choose with whatever you find more convenient at the time. For many mathematical objects there are many definitions, and you just pick whatever suits your problem (assuming of course you have shown them identical).

Is it sometimes true that, people concerned with "pure mathematics" may often choose an approach to things that is completely unmotivated by real examples, suggesting that this approach is representative of "what's really going on" even though the motivated approach and the unmotivated approach are logically identical, and the former just makes more sense?

If they are logically equivalent, then the mathematician should be able to choose the one he prefers whether he gives "real world motivation" or not. If he prefer to work with the one you call unmotivated, then it becomes motivated by the fact that it's useful (the motivation is the usefulness rather than analogy). There is no need to give preferential treatment to one point of view. Intuition can be hard to explain, but if he gives vague statements like an approach representing what's really going on, then that probably just means that he has better intuition about this approach. This is enough motivation as it will allow him to more easily understand it (whether it comes from a physical object or not).
 
HallsofIvy said:
There is no such hierarchy. Yes, you can start with "sets" and build up mathematics from that. But you can also start with other things, such as, say, group theory, defining the objects in some abstract manner (when you have a set of objects with operations defined on them, it is always possible to define the operations first and then take the objects as "given" by the operations) and then derive set theory from that. There are simply too many interconnections between mathematics to set up any "natural" hierarchy.

I don't know whether I agree. Yes you can definitely start with other fundamental objects and build set theory from that. But I thought it was the vast consensus in the mathematical community that modern day math should ultimately have ZFC as its starting point.
 
That is a convention, not a consensus on the structure of mathematics.
 
HallsofIvy said:
That is a convention, not a consensus on the structure of mathematics.

Well yea, but math is man made anyways. The conventions define the subject.
 

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