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Let $q: \mathbb{R^3}\to \mathbb{R},\ q(x_1, x_2, x_3)=-5x_1^2-x_2^2-x_3^2+2x_1x_3+2x_2x_3-4x_1x_2$ be a quadratic form.

Find a maximal subspace $W \subseteq \mathbb{R^3}$ such that $\forall w \in W,\ q(w) \geq 0$.

Using row/column operations on $[q]_e$, I got to the canonical form: $\text{diag}(-1, -1, 1)$.

That tells me that there exists a basis $(u)=(u_1, u_2, u_3)$ such that: $$[v]_u=\begin{pmatrix} x \\ y \\ z \end{pmatrix},\ q(v)=-x^2-y^2+z^2$$

So if $w=\alpha u_3,\ q(w)=\alpha^2 \geq 0$, therefore $w \in W$. So far I've shown $\text{span}(u_3) \subseteq W$.

If we assume that there exists $W\subset {W}'$ such that ${W}'$ is maximal, then $\forall {w}' \in {W}'$: $$q({w}')=-w_1^2-w_2^2+w_3^2\geq 0,\ [{w}']_u=\begin{pmatrix} w_1 \\ w_2 \\ w_3 \end{pmatrix}$$

But if we assume ${w}' \notin W$ then $w_1 \neq 0$ or $w_2 \neq 0$.

At this point I'm stuck, not sure how to finish this up.

1 Answers 1

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It is a standard result that the signature of a quadratic form is well-defined. You have found the canonical form $\text{diag}(-1,-1,1)$, so the signature is $(1,2)$. Now the number of +1's (the first number of the signature) equals the maximal dimension of a subspace on which the form is positive definite. E.g. see my proof here. So in this case any 1-dimensional space on which the form is positive definite, is maximal. So your $\text{span}(u_3)$ is indeed maximal.

Let me apply the argument I linked to to the current case. Suppose $V\supset \text{span}(u_3)$ is a subspace on which $q$ is positive definite. Then $q$ is both positive and negative definite on the subspace $V\cap \text{span}(u_1,u_2)$. Of course this implies that this subspace is $\{0\}$. But, $\{u_1,u_2,u_3\}$ being a basis, $V\supset \text{span}(u_3)$ combined with $V\cap \text{span}(u_1,u_2)=\{0\}$ implies $V= \text{span}(u_3)$. Hence $\text{span}(u_3)$ is maximal.

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    I must say I didn't completely understand your proof there. Could you point out how to finish the proof I started?2011-07-10
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    Well, if you think of the standardized form, the subspace consisting of $x = y =0$ is contained in the required space. But if there are any other elements in the subspace, then we can find a non-zero element in the subspace with $z$-component $0$. But the form takes strictly negative value on any such element.2011-07-10
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    @daniel [in your notation]: if $w_3=0$ then $q(w')\geq 0$ (by assumption) and $q(w')=-w_1^2-w_2^2\leq 0$ (because squares are nonnegative), hence $w_1=w_2=0$. In other words $W'\cap \text{span}(u_1,u_2)=\{0\}$. Now we are in the second to last sentence of my answer, and conclude $W'=\text{span}(u_1,u_2)$.2011-07-10
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    @Geoff: why must $z=0$?2011-07-10