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Let $A\in \mathbb{C}^{ n\times n}$ and $B \in \mathbb{C}^{p \times p}$ be Hermitian matrices with $p < n$.

Find matrix $X$ such that $X^*AX=B.$

Solution in the case of positive definite $A$ and $B$ was given here.

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  • $\begingroup$ Almost identical, but for positive definite $A$: mathoverflow.net/questions/288443/…. I suppose a similar idea works, assuming $rk(A) \geq rk(B)$ (otherwise clearly there is no solution). $\endgroup$ Commented Feb 14, 2018 at 13:19
  • $\begingroup$ Is your $T$ a conjugate transpose? $\endgroup$ Commented Feb 14, 2018 at 13:22
  • $\begingroup$ It is conjugate transpose. I have found a parametric solution for $A>0$. But I want solution for arbitrary Hermitian matrix $A$. $\endgroup$
    – Saheb
    Commented Feb 14, 2018 at 13:30

1 Answer 1

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There are $P\in U(n),Q\in U(p)$ s.t. $A=P^*\Delta P,Q^*BQ=D$ where $\Delta,D$ are diagonal real; then

$Q^*X^*P^*\Delta PXQ=D$, that is

$(1)$ $U^*\Delta U=D$, where $PXQ=U=[u_{i,j}]\in M_{n,p}$ or $X=P^{-1}UQ^{-1}$.

Equation $(1)$ is a system of $p(p+1)$ equations in the $2np$ real unknowns $Re(u_{i,j}),Im(u_{i,j})$.

We assume that $rank(B)=p$. If $rank(A)<p$, then, clearly, there are no solutions; assume that $n\geq rank(A)\geq p$

$\textbf{Proposition 1}$. Let $signature(\Delta)=(k+,l-),signature(D)=(r+,(p-r)-)$. If $k\geq r,l\geq p-r$, then there are many solutions in $U$ that depend at least on $p^2$ real parameters. When $rank(A)=p$, the solutions depend at least on $2np-p^2$ parameters;

$\textbf{Proof}$. We may assume that $\Delta=diag(\epsilon_{n-p},\delta_p)$, where $signature(\delta)=signature(D)$ and $U=\begin{pmatrix}V\\W_p\end{pmatrix}$; we impose $V=0$. Then $(1)$ can be written

$(2)$ $W^*\delta W=D$ where all the matrices are $p\times p$ and invertible.

$(2)$ is a system of $2p(p-1)/2+p=p^2$ equations in $2p^2$ real unknowns and moreover, $(2)$ admits real solutions $W$ (if $\Delta$ and $D$ have distinct eigenvalues, then $W$ is associated to a permutation of the elements of the basis, then to homotheties). We deduce the first result.

Now, if $rank(A)=p$, then $\epsilon=0$ and $V$ is arbitrary. We obtain at least $2p(n-p)+p^2=2np-p^2$ parameters.

EDIT. I forgot to say and to prove that the condition "$k\geq r,l\geq p-r$", in Proposition 1, is necessary.

$\textbf{Proposition 2.}$ Let $A,B\in M_n$ be Hermitian and $U\in M_{p,n}$ s.t. $U^*AU=B$. If $signature(A)=(k+,l-)$ and $signature(B)=(r+,s-)$ (we don't write the zeroes), then $k\geq r,l\geq s$.

$\textbf{Proof}$. Let $Z=[0,U]\in M_n$. Then $Z^*AZ=diag(0_{n-p},B)$. There is a sequence $(Z_m)_m$, in $GL_n$, that converges to $Z$. For every $m$,

$spectrum(Z_m^*AZ_m)=\{\lambda_{m,1},\cdots,\lambda_{m,k},\mu_{m,1},\cdots,\mu_{m,l},0_{n-k-l}\}$ where the $\lambda's$ are $>0$ and the $\mu's$ are $<0$. Since $Z_m^*AZ_m$ converges to $diag(0_{n-p},B)$, there is a permutation of $\lambda's$ and $\mu's$ s.t. $\lambda_{m,j}$ converges to $0$ or to a $>0$ eigenvalue of $B$ and $\mu_{m,j}$ converges to $0$ or to a $<0$ eigenvalue of $B$. $\square$.

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  • $\begingroup$ Equation (2) is a system of $p(p+1)/2$ equations in $2np$ real unknowns. $\endgroup$
    – Saheb
    Commented Sep 16, 2018 at 6:38
  • $\begingroup$ @Saheb , recalculate my friend. $W$ is $p\times p$ and $W^*\delta W$ is characterized by its upper right half part and has a real diagonal... $\endgroup$
    – loup blanc
    Commented Sep 16, 2018 at 9:26

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