Difference between revisions of "Open Problems:62"
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− | Given a symmetric matrix $A$, we can think of PCA as maximizing $x^\top A x$ subject to $\|x\|=1$. If we also add the condition $x \ge 0$, this problem becomes NP-hard. | + | Given a symmetric matrix $A$, we can think of Principal Component Analysis (PCA) as maximizing $x^\top A x$ subject to $\|x\|=1$. If we also add the condition $x \ge 0$, this problem becomes NP-hard. |
We can define a convex relaxation: | We can define a convex relaxation: | ||
− | \[ \max Tr(WA) \ \text{s.t}\ | + | \[ \max \operatorname{Tr}(WA) \quad \text{s.t.} \quad \operatorname{Tr}(W) = 1,\ \ W \ge 0,\ \ W \succeq 0. \] |
− | Suppose that $A$ is a random matrix | + | Suppose that $A$ is a random matrix. In particular, set $A_{ij}$ to be i.i.d $N(0,1)$. Then empirical results show that the resulting $W$ is a rank-1 matrix, which means that we recover the optimal $x$ exactly. |
− | Is this true in general ? Note that we can prove that the solution is rank 1 if $A = v v^T + | + | Is this true in general? Note that we can prove that the solution is rank 1 if $A = v v^T + (\text{small amount of noise})$. |
Latest revision as of 22:56, 13 June 2014
Suggested by | Andrea Montanari |
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Source | Bertinoro 2014 |
Short link | https://sublinear.info/62 |
Given a symmetric matrix $A$, we can think of Principal Component Analysis (PCA) as maximizing $x^\top A x$ subject to $\|x\|=1$. If we also add the condition $x \ge 0$, this problem becomes NP-hard. We can define a convex relaxation:
\[ \max \operatorname{Tr}(WA) \quad \text{s.t.} \quad \operatorname{Tr}(W) = 1,\ \ W \ge 0,\ \ W \succeq 0. \]
Suppose that $A$ is a random matrix. In particular, set $A_{ij}$ to be i.i.d $N(0,1)$. Then empirical results show that the resulting $W$ is a rank-1 matrix, which means that we recover the optimal $x$ exactly.
Is this true in general? Note that we can prove that the solution is rank 1 if $A = v v^T + (\text{small amount of noise})$.