Suggest edit — Linear Algebra Errors

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title: "Linear Algebra Errors"
source: https://www.jemoka.com/posts/kbhlinear_algebra_errors-1/
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Gaussian Elimination Quiz Demonstrate that matrices&rsquo; multiplication are not commutative (error: didn&rsquo;t consider \(m\times m\)) Which \(2\times 2\) matrices under multiplication form a group? (error: closure need to proved on invertable matrices under multiplication, not just \(2\times 2\)) Deriving Rotation matrices (error: clockwise vs counter-clockwise) Linear Independence Quiz Connection between linear independence and systems equations (error: beated around the bush) &mdash; the matrix of an nxn system of equations has a solution if the matrix&rsquo;s column vectors is linearly independent Basis and Dimension Quiz put 0 into a basis AAAA not lin. indep; figure out what the basis for a polynomial with a certain root is: it is probably of dimension m (instead of m+1), because scalars doesn&rsquo;t work in the case of p(3)=0; so basis is just the scalars missing some inequality about basis? &mdash; its just that lin.idp sets is shorter or equal to basis and spanning sets is longer or equal to basis Final, part 1 definition of vector space: scalar multiplication is not an operation straight forgot \(dim(U+V) = dim U + dim V - dim (U\cap V)\) plane containing \((1,0,2)\) and \((3,-1,1)\): math mistake proof: det A det B = det AB Final, part 2 Counterproof: If \(v_1 \dots v_4\) is a basis of \(V\), and \(U\) is a subspace of \(V\) with \(v_1, v_2 \in U\) and \(v_3, v_4\) not in \(U\), \(v_1, v_2\) is a basis of \(U\) Counterproof: if \(T \in \mathcal{L}(V,V)\) and \(T^{2}=0\), then \(T=0\) Counterproof: if \(s,t \in \mathcal{L}(V,V)\), and \(ST=0\), then \(null\ s\) is contained in \(range\ T\) Product Spaces Quiz Prove that \(\mathcal{L}(V_1 \times V_2 \times \dots \times V_{m}, W)\) and \(\mathcal{L}(V_1, W) \times \dots \times \mathcal{L}(V_{m}, W)\) are isomorphic
error: didn&rsquo;t do it
Quotient Spaces Quiz Couldn&rsquo;t prove that the list in linearly independent: the linear combinations is some \(c_1v_1 + \dots c_{m}v_{m} + U\); as \(v_1 \dots v_{m}\) is a basis of \(V / U\), \(c_1 \dots c_{m} = 0\), now the second part is also a basis so they are \(0\) too. The spanning proof: \(v + U =\) , rewrite as basis, etc.