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Proof Index ~ Definitions ~ Sandbox
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| Definitions:4,091
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Latest Proof: Ring of Integers is Principal Ideal Domain/Proof 2 on 17 May 2012 by Prime.mover
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Top 10 Wanted Proofs
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- Frobenius's Theorem --Matt Westwood 18:38, 8 November 2008 (UTC)
- Wedderburn's Theorem --Matt Westwood 18:38, 8 November 2008 (UTC)
- Whitney Immersion Theorem --Matt Westwood 08:09, 18 January 2009 (UTC)
- Whitney Embedding Theorem --Matt Westwood 08:09, 18 January 2009 (UTC)
- Topological h-Cobordism Theorem --Matt Westwood 08:09, 18 January 2009 (UTC)
- Thurston's Geometrization Conjecture --Matt Westwood 08:09, 18 January 2009 (UTC)
- Tartaglia's Formula --Matt Westwood 06:39, 15 March 2009 (UTC)
- Burnside's Theorem --Joe (talk) 16:50, 16 March 2009 (UTC)
- Abel-Ruffini Theorem [1] --Matt Westwood 20:45, 16 March 2009 (UTC)
- Central Limit Theorem --HrMeyer 20:53, 23 April 2009 (UTC)
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Want to do something different? Check here for articles linked to but not created, or finish a stub article.
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News
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April 1, 2012
- Now the Riemann Hypothesis has finally been solved (who would have guessed that it would be soluble relying solely upon analysis of elementary functions?) someone's going to have to go and post it up. I'll get there but I'm bogged down in tidying up the Relation Theory category. --prime mover
March 11, 2012
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Migrating to a different RSS renderer since the one we currently use seems to no longer be maintained. It appears an upstream version in 1.19 is being supported, going to switch to that. --Joe (talk)
February 12, 2012
- Trying out the new 2.0 beta of MathJax. --Joe
November 30, 2011
- Check out the forthcoming AI Mashup Challenge - fancy a mathematics conference in sunny Greece?
November 10, 2011
- Still getting a lot of what I think are spam accounts being created (since the email confirmation messages all bounce back). Trying to combat this by checking all IP's against SORBS. --Joe (talk) 11:50, 10 November 2011 (CST)
November 9, 2011
- So, spam sucks! We're moving back to a user based, email authenticated edit system ... effective immediately. If anyone has doesn't like this, let me know. --Joe (talk) 05:49, 9 November 2011 (CST)
November 7, 2011
- 600 registered users. Less than 2 months for 100 more users to join, but quite a few of those were spamming accounts and have now been blocked. --prime mover 17:11, 7 November 2011 (CST)
September 30, 2011
- Using ReCaptcha for account creation and anonymous posts. Hopefully this will cut down on some of the spam we've been seeing recently. --Joe (talk) 16:36, 30 September 2011 (CDT)
September 12, 2011
- 500 registered users. Just over 3 months for 100 more users to join. --prime mover 00:27, 12 September 2011 (CDT)
September 3, 2011
September 1, 2011
- The 4000th proof page has been added, although the proof itself still needs to be done.
Show All News
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Proof of the Week
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Linear Transformation as Matrix Product
Theorem
Let $T: \R^n \to \R^m, \mathbf x \mapsto T\left({\mathbf x}\right)$ be a linear transformation.
Then $T\left({\mathbf x}\right) = \mathbf A_T \mathbf x$, where $\mathbf A_T$ is the $m \times n$ matrix defined as:
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \mathbf A_T\)
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\(=\)
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\(\displaystyle \begin{bmatrix} \\ \\ \\ T\left({\mathbf e_1 }\right) & T\left({\mathbf e_2 }\right) & \cdots & T\left({\mathbf e_n }\right) \\ \\ \\ \end{bmatrix}\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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where $\left \{ {\mathbf e_1, \mathbf e_2, \cdots, \mathbf e_n} \right\}$ is the standard basis of $\R^n$.
Proof
Let $\mathbf x = \begin{bmatrix} x_1 \\ x_2 \\ \vdots \\ x_n \end{bmatrix}$.
Let $\mathbf I_n$ be the identity matrix of order $n$.
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \mathbf x_{n \times 1}\)
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\(=\)
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\(\displaystyle \mathbf I_n \mathbf x_{n \times 1}\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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definition of left identity
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(=\)
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\(\displaystyle \begin{bmatrix}
1 & 0 & \cdots & 0 \\
0 & 1 & \cdots & 0 \\
\vdots & \vdots & \ddots & \vdots \\
0 & 0 & \cdots & 1 \\
\end{bmatrix}\begin{bmatrix} x_1 \\ x_2 \\ \vdots \\ x_n \end{bmatrix}\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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Identity Matrix is Identity:Lemma
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(=\)
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\(\displaystyle \begin{bmatrix} \\ \\ \\ \mathbf e_1 & \mathbf e_2 & \cdots & \mathbf e_n \\ \\ \\ \end{bmatrix}\begin{bmatrix} x_1 \\ x_2 \\ \vdots \\ x_n \end{bmatrix}\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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definition of standard basis
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(=\)
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\(\displaystyle \sum_{i=1}^n \mathbf e_i x_i\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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definition of matrix multiplication
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle T\left({\mathbf x}\right)\)
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\(=\)
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\(\displaystyle T\left({\sum_{i=1}^n \mathbf e_i x_i}\right)\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(=\)
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\(\displaystyle \sum_{i=1}^n T\left({\mathbf e_i}\right)x_i\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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definition of linear transformation
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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\(=\)
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\(\displaystyle \begin{bmatrix} \\ \\ \\ T\left({\mathbf e_1}\right) & T\left({\mathbf e_2}\right) & \cdots & T\left({\mathbf e_n}\right) \\ \\ \\ \end{bmatrix} \begin{bmatrix} x_1 \\ x_2 \\ \vdots \\ x_n \end{bmatrix}\)
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\(\displaystyle \)
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\(\displaystyle \)
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\(\displaystyle \)
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definition of matrix multiplication
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That $\mathbf A_T$ is $m \times n$ follows from each $T\left({\mathbf e_i}\right)$ being a member of $\R^m$ and thus having $m$ rows.
$\blacksquare$
Also see
Sources
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