What are the implications of Gödel's incompleteness theorems for the foundations of mathematics, and how do they relate to other areas of philosophy and computer science?
Gödel's incompleteness theorems, established by Kurt Gödel in the early 20th century, hold significant implications for the foundations of mathematics and maintain close ties to diverse areas of philosophy and computer science.

The two incompleteness theorems can be briefly stated as follows:

1. First Incompleteness Theorem: In any consistent formal system capable of expressing basic arithmetic, there exist statements that cannot be proven or disproven within the system.
2. Second Incompleteness Theorem: No consistent formal system capable of expressing basic arithmetic can prove its own consistency.

Consequences for the foundations of mathematics:

1. Incompleteness: Gödel's theorems ended the quest for a complete and consistent axiomatic system encompassing all of mathematics, revealing that true statements will always exist that cannot be proven within the system.
2. Formalism Limitations: The incompleteness theorems exposed the inherent limitations of formalism, a prevalent view that mathematics could be wholly reduced to symbol manipulation following a set of formal rules.
3. Undecidability: The theorems introduced the concept of undecidable statements, which are neither provable nor disprovable within a given formal system. This idea later impacted the development of computational theory and computer science.

Connections to other areas of philosophy:

1. Epistemology: Gödel's theorems call into question the notion of complete and certain knowledge in any given domain, suggesting that our understanding of the world is inherently limited.
2. Philosophy of Mathematics: The theorems carry implications for various philosophical positions on the nature of mathematical entities.
3. Metaphysics: Gödel's theorems provoke questions about the nature of reality and the possibility of a complete and consistent description of the universe.

Connections to computer science:

1. Halting Problem: Gödel's ideas inspired Alan Turing's work, leading to the development of the Turing machine and the proof that the Halting Problem is undecidable.
2. Complexity Theory and Artificial Intelligence: The undecidability results from Gödel's theorems contributed to the emergence of complexity theory, which examines the intrinsic difficulty of solving computational problems, and influenced the study of artificial intelligence, particularly in automated theorem proving and machine learning.

In summary, Gödel's incompleteness theorems have far-reaching consequences for not only the foundations of mathematics but also various areas of philosophy and computer science, including epistemology, the philosophy of mathematics, metaphysics, the Halting Problem, complexity theory, and artificial intelligence.
Do these theorems help us understand anything about AGI or the possible creation of AGI?
While these theorems don't imply we cannot create human level artificial general intelligence, they do imply that any intelligence we create will always have to accept the fact that certain statements are impossible to prove the same way human mathematicians have to. No amount of intelligence will change this, since it is already proved that these statements cannot be proved.