Difference between revisions of "The limits and guesses in math"
From apm
(Added link to very nice new video related to the topic) |
m (minor edit as math not necessarily counts as science) |
||
(4 intermediate revisions by the same user not shown) | |||
Line 1: | Line 1: | ||
{{stub}} | {{stub}} | ||
{{speculative}} | {{speculative}} | ||
− | math is not | + | Even math is not achieving absolute truth. |
− | + | There is no way around faith in at least a few axioms outside the proof system. | |
+ | |||
+ | Disclamer #1: | ||
+ | * Math is the best and most formal system we have and (as it very much looks) the best and most formal system we will ever have | ||
+ | * This page is not meant to undermine the faith in math and science. | ||
+ | Disclaimer #2: | ||
+ | * All "certainties" in this article (and anywhere else in this universe) are in the very end only certainties to the degree of practicability from experience. | ||
+ | |||
+ | == About realizing the unprovability of fundamental axioms == | ||
+ | |||
+ | Here's a way how one could maybe question one of the most fundamental axioms of math: | ||
+ | That every natural number has an successor. | ||
Does a number which is not representable by the means that our universe provide ([[big bang as spontaneous demixing event|amount of demixing in the big bang]]) even exist? | Does a number which is not representable by the means that our universe provide ([[big bang as spontaneous demixing event|amount of demixing in the big bang]]) even exist? | ||
Ridiculously large numbers can easily be represented by simple compression methods (e.g. the Ackermann-function) but between those numbers there are gaping holes of unrepresentability. | Ridiculously large numbers can easily be represented by simple compression methods (e.g. the Ackermann-function) but between those numbers there are gaping holes of unrepresentability. | ||
While we don't know which of the ridiculously big numbers we can represent in a smaller compressed form we can be certain that there are many more which certainly can't be represent within the limits of our universe. | While we don't know which of the ridiculously big numbers we can represent in a smaller compressed form we can be certain that there are many more which certainly can't be represent within the limits of our universe. | ||
− | |||
− | |||
== Related == | == Related == | ||
Line 20: | Line 29: | ||
* beauty as scale variant inhomogeneous anisotropic structures on all scales | * beauty as scale variant inhomogeneous anisotropic structures on all scales | ||
* Helmholz free energy {{WikipediaLink|https://en.wikipedia.org/wiki/Helmholtz_free_energy}} | * Helmholz free energy {{WikipediaLink|https://en.wikipedia.org/wiki/Helmholtz_free_energy}} | ||
+ | * [[A true but useless theory of everything]] | ||
+ | * [[Foundations of mathematics]] | ||
+ | * [[Philosophical topics]] | ||
[[Category:Philosophical]] | [[Category:Philosophical]] |
Latest revision as of 19:23, 11 February 2024
Even math is not achieving absolute truth. There is no way around faith in at least a few axioms outside the proof system.
Disclamer #1:
- Math is the best and most formal system we have and (as it very much looks) the best and most formal system we will ever have
- This page is not meant to undermine the faith in math and science.
Disclaimer #2:
- All "certainties" in this article (and anywhere else in this universe) are in the very end only certainties to the degree of practicability from experience.
About realizing the unprovability of fundamental axioms
Here's a way how one could maybe question one of the most fundamental axioms of math: That every natural number has an successor.
Does a number which is not representable by the means that our universe provide (amount of demixing in the big bang) even exist? Ridiculously large numbers can easily be represented by simple compression methods (e.g. the Ackermann-function) but between those numbers there are gaping holes of unrepresentability. While we don't know which of the ridiculously big numbers we can represent in a smaller compressed form we can be certain that there are many more which certainly can't be represent within the limits of our universe.
Related
- the severe limitedness of pseudo random number generators - inaccessibility of vast ranges
- Chaitin's omega constant that encodes the solution of all encodable problem descriptions
- The halting problem - The program that executes all construable programs in cantor triangle style - A true but useless theory of everything
- Kurt Gödels incompleteness theorem
- perfect order perfect chaos and interesting structure in between
- what distinguishes interesting entropy states from bland entropy states?
- beauty as scale variant inhomogeneous anisotropic structures on all scales
- Helmholz free energy (leave to Wikipedia - please come back again)
- A true but useless theory of everything
- Foundations of mathematics
- Philosophical topics
External links
- Youtube: This is Math's Fatal Flaw – by Veritasium – 2021-05-22