Notes for AKT-090917-1/0:46:11: Difference between revisions

Latest revision as of 20:38, 18 September 2009

Let $K$ be a knot, $J_{K}(q)$ be its Jones polynomial. Substitute $q=e^{x}$ and expand $J_{k}(e^{x})$ into power series. We have $J_{K}(e^{x})=\sum _{n}j_{(n,K)}\ x^{n}$ where the coefficients $j_{(n,\cdot )}:\{knots\}\rightarrow \mathbb {Z}$ are knot invariants.

Thm: $j_{(n,\cdot )}$ is of type $n$ .

Revision as of 20:37, 18 September 2009 (view source) Conan777 (talk \| contribs) No edit summary		Latest revision as of 20:38, 18 September 2009 (view source) Conan777 (talk \| contribs) No edit summary
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	Let <math>K</math> be a knot, <math>J_K(q)</math> be its Jones polynomial. Substitute <math>q = e^x</math> and expand <math>J_k(e^x)</math> into power series. We have <math>J_K(e^x) = \sum_n j_{n,K} \ x^n</math> where the coefficients <math>j_{n,\cdot}: \{knots \} \rightarrow \mathbb{Z}</math> are knot invariants.		Let <math>K</math> be a knot, <math>J_K(q)</math> be its Jones polynomial. Substitute <math>q = e^x</math> and expand <math>J_k(e^x)</math> into power series. We have <math>J_K(e^x) = \sum_n j_{(n,K)} \ x^n</math> where the coefficients <math>j_{(n,\cdot)}: \{knots \} \rightarrow \mathbb{Z}</math> are knot invariants.

	Thm: <math>j_{n, \cdot}</math> is of type <math>n</math>.		Thm: <math>j_{(n, \cdot)}</math> is of type <math>n</math>.

Notes for AKT-090917-1/0:46:11: Difference between revisions

Latest revision as of 20:38, 18 September 2009

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