$ \newcommand{\braket}[1]{\langle #1 \rangle} \newcommand{\abs}[2][]{\left\lvert#2\right\rvert_{\text{#1}}} \newcommand{\ket}[1]{\left\lvert#1 \right.\rangle} \newcommand{\bra}[1]{\langle\left. #1\right\rvert} \newcommand{\braket}[1]{\langle #1 \rangle} \newcommand{\dd}{\text{d}} \newcommand{\dv}[2]{\frac{\dd #1}{\dd #2}} \newcommand{\pdv}[2]{\frac{\partial}{\partial #1}} $
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If $V$ is finite dimensional with dimension $n$ and $T:V\to V$ has $n$ distinct eigenvalues, then it is diagonalizable.

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If $V$ is finite dimensional with dimension $n$ and $T:V\to V$ has $n$ distinct eigenvalues, then it is diagonalizable.

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result
concepts
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proof
FullPage
result
concepts
hypothesis
implications
proof
If $V$ is finite dimensional with dimension $n$ and $T:V\to V$ has $n$ distinct eigenvalues, then it is diagonalizable.

Concepts

Coming soon

Hypothesis

Coming soon

Results

Coming soon

Proof

Coming soon
If $V$ is finite dimensional with dimension $n$ and $T:V\to V$ has $n$ distinct eigenvalues, then it is diagonalizable.

Concepts

Coming soon

Hypothesis

Coming soon

Results

Coming soon

Proof

Coming soon
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result
concepts
hypothesis
implications
proof