Fermat's equation solution in Z

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In summary, there are integers a, b, and c that satisfy the equation an + bn = cn for n>2, even if a, b, or c is negative. This can be proven by rearranging the terms and finding solutions with positive integers. There can also be solutions with one of the numbers being 0, such as 64+04=64 and 53+(-5)3=03. However, there can be no solution with all non-zero numbers, as proven by the non-existence of positive solutions.
  • #1
avery
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hi,

is there integers a, b, c that satisfy the equation an + bn = cn for n>2
(I don't mean positive integers)

thx.
 
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  • #2
I assume you mean an + bn = cn. Even if a, b, or c is negative, it won't make any difference. If n is even, it is obvious, while if n is odd you can replace the negative by its positive counterpart and rearrange terms so the equation is in its original form.
 
  • #3
There are many solutions where one of the numbers is 0: two examples are 64+04=64 and 53+(-5)3=03.

There can be no solution with non-zero numbers, and this can be inferred from non-existance of positive solutions.
For even n, this is trivial: since an=(-a)n, a solution with negatives is also a solution with positive integers.
For odd n, (-a)n=-an, and you can always rearrange the terms to have a solution in positive numbers. This is a bit different for each assignment of signs to a, b, and c, but as an example, if a<0,b>0,c>0 and an+bn=cn, then cn+(-a)n=bn is a solution in positive numbers.
 

1. What is Fermat's equation in Z?

Fermat's equation in Z, also known as Fermat's Last Theorem, is a mathematical equation proposed by Pierre de Fermat in the 17th century. It states that there are no positive integer solutions for the equation x^n + y^n = z^n for n > 2.

2. Why is Fermat's equation in Z significant?

Fermat's equation in Z is significant because it is one of the most famous and long-standing unsolved problems in mathematics. It has challenged and inspired mathematicians for centuries, and its eventual proof in 1995 by Andrew Wiles was a major breakthrough in the field of number theory.

3. Can Fermat's equation in Z be solved for values of n other than 2?

No, Fermat's equation in Z is only applicable for values of n greater than 2. For values of n equal to 2, the equation has infinitely many solutions, known as Pythagorean triples.

4. Are there any exceptions to Fermat's equation in Z?

No, there are no known exceptions to Fermat's equation in Z. It has been extensively tested and proven for all possible values of the variables x, y, z, and n.

5. How is Fermat's equation in Z related to other areas of mathematics?

Fermat's equation in Z has connections to many areas of mathematics, including number theory, algebraic geometry, and modular forms. It has also inspired the development of new mathematical techniques and theories, such as the Taniyama-Shimura conjecture and the theory of elliptic curves.

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