Let $M$ be the vector space of all $n\times n$ matrices and $T:M\to M$ be a linear transformation such that $T(A) = 0$, where $A$ denotes all symmetric and skew symmetric matrices. Then what is the rank of $T$? $\mathrm{rank}(T) = \dim(M)-\mathrm{nullity}(T)$. Dimension of $M$ is $n^2$ but what is its nullity?
What is the rank of a linear map $T$ on the space of $n\times n$ matrices such that $T(A)=0$ for any symmetric or skew-symmetric matrices?
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linear-algebra
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2My previous question may be obsolete, but I will note: The idea that $T$ could be simply the $0$ map could come without knowing much. Even if there could be other maps that satisfy the given condition, the $0$ map is certainly an option. Hence if the question has a unique answer, you have it there. However, that in itself doesn't tell you why there is a unique answer, and for that Zev's approach is good. – 2012-12-24
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Hint: Considering the case of $n=2$, observe that any $2\times 2$ matrix can be written as $\begin{pmatrix}a & b \\ c & d\end{pmatrix}=\begin{pmatrix}a & \tfrac{b+c}{2} \\ \tfrac{b+c}{2} & d\end{pmatrix}+\begin{pmatrix}0 & \tfrac{b-c}{2} \\ \tfrac{c-b}{2} & 0\end{pmatrix}$ Can you generalize this observation? What does this imply about how $T$ acts on any matrix?
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0Yup, that's right! – 2012-12-24