Let $Y\left(t\right)$ be a matrix function, then does $\frac{d}{dt}Y^{T}Y=O$ necessarily imply $Y^{T}\left(t\right)Y\left(t\right)\equiv I$ ? Why or why not? Here $Y^{T}$ the transpose of $Y$ , $O$ zero matrix and $I$ the identity matrix.
Differential equation for a matrix-valued function
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matrices
derivatives
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0@Jack Let's exclude the trivial case when $Y\left(t\right)=$const. At first sight, it appears that $Y^{T}Y$ can be any constant matrix, but what I am hoping is that somebody can give me a proof that this is not the case, that the only choice is the identity matrix. I konw there is something special about $Y^{T}Y$, such as symmetric, so definitely not any constant matrix ! – 2012-02-29
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The correct conclusion from $\frac{d}{dt}(\text{something})=0$ is that $\text{(something)}$ does not depend on $t$. This is all one can get, because any function independent of $t$ has zero derivative with respect to $t$.
But if it is also known that $Y(t_0)$ is orthogonal for some $t_0$, then from $Y^T(t_0)Y(t_0)=I$ it indeed follows that $Y^TY\equiv I$.