Relation between different presentations of a positive semidefinite matrix











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Let $P$ be a positive semidefinite $ntimes n$ matrix of rank $r$. Then we may write $$ P=sum_{j=1}^r v_jv_j^*, text{where} v_1,ldots,v_rinmathbb C^n.$$



If we also have $P=sum_{j=1}^r w_jw_j^*$ for some $w_1,ldots,w_rinmathbb C^n$,




What's the relation between $v_1,ldots,v_r$ and $w_1,ldots,w_r$?











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    Let $P$ be a positive semidefinite $ntimes n$ matrix of rank $r$. Then we may write $$ P=sum_{j=1}^r v_jv_j^*, text{where} v_1,ldots,v_rinmathbb C^n.$$



    If we also have $P=sum_{j=1}^r w_jw_j^*$ for some $w_1,ldots,w_rinmathbb C^n$,




    What's the relation between $v_1,ldots,v_r$ and $w_1,ldots,w_r$?











    share|cite|improve this question


























      up vote
      2
      down vote

      favorite









      up vote
      2
      down vote

      favorite











      Let $P$ be a positive semidefinite $ntimes n$ matrix of rank $r$. Then we may write $$ P=sum_{j=1}^r v_jv_j^*, text{where} v_1,ldots,v_rinmathbb C^n.$$



      If we also have $P=sum_{j=1}^r w_jw_j^*$ for some $w_1,ldots,w_rinmathbb C^n$,




      What's the relation between $v_1,ldots,v_r$ and $w_1,ldots,w_r$?











      share|cite|improve this question















      Let $P$ be a positive semidefinite $ntimes n$ matrix of rank $r$. Then we may write $$ P=sum_{j=1}^r v_jv_j^*, text{where} v_1,ldots,v_rinmathbb C^n.$$



      If we also have $P=sum_{j=1}^r w_jw_j^*$ for some $w_1,ldots,w_rinmathbb C^n$,




      What's the relation between $v_1,ldots,v_r$ and $w_1,ldots,w_r$?








      linear-algebra matrices functional-analysis






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      edited Nov 22 at 22:16

























      asked Nov 22 at 4:20









      Martin Argerami

      123k1176174




      123k1176174






















          2 Answers
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          I am not sure what purpose does your exercise serve, but the answer can be more succinct. Put together the vectors $v_i$s to form a matrix $V$ and define $W$ analogously. Then both $V$ and $W$ have full column ranks and $VV^ast=WW^ast$. Hence $V^ast x=0$ if and only if $W^ast x=0$, i.e. the column spaces of $V$ and $W$ have a common orthogonal complement $mathcal X$. Let $X$ be a matrix whose columns form a basis of $mathcal X$. Then both augmented matrices $[V|X]$ and $[W|X]$ are invertible. Since $VV^ast=WW^ast$, we get $[V|X][V|X]^ast = [W|X][W|X]^ast$. Thus $U=[W|X]^{-1}[V|X]$ is a unitary matrix and $V=WU$.






          share|cite|improve this answer























          • Very neat. $ $
            – Martin Argerami
            Nov 22 at 5:27


















          up vote
          1
          down vote













          The relation is that there exists a unitary $Uin M_r(mathbb C)$ such that $$w_j=sum_{k=1}^r U_{jk}v_k.$$



          Indeed, fix an orthonormal basis $e_1,ldots,e_n$ of $mathbb C^n$, and we may write
          $$
          v_k=sum_{k=1}^ns_{jk}e_j, w_k=sum_{j=1}^rt_{jk}e_j.
          $$

          Now consider $S,Tin M_r(mathbb C)$ with $S_{kj}=s_{kj}$, $T_{kj}=t_{kj}$. Then
          $$
          P=sum_{k=1}^rv_kv_k^*=sum_{k=1}^rsum_{j,ell=1}^rs_{jk}overline{s_{ell k}}e_je_ell^*=sum_{k=1}^rsum_{j,ell=1}^rS_{jk}{(S^*)_{k ell}}e_je_ell^*=sum_{j,ell=1}^r(SS^*)_{jell}e_je_ell^*.
          $$

          Similarly,
          $$
          P=sum_{j,ell=1}^r(TT^*)_{jell}e_je_ell^*.
          $$

          As $e_je_ell^*$ are the matrix units in $M_r(mathbb C)$, we get that $TT^*=SS^*$. Now we write the polar decompositions
          $$
          S^*=W(SS^*)^{1/2}, T^*=V(TT^*)^{1/2},
          $$

          where $W,V$ are unitaries. Then $S=(SS^*)^{1/2}W^*$, and
          $$
          T=(TT^*)^{1/2}V^*=(SS^*)^{1/2}V^*=SWV^*=SZ,
          $$

          where $Z=WV^*$. Now
          begin{align}
          w_j&=sum_{k=1}^r t_{kj}e_k=sum_{k=1}^r(SZ)_{kj}e_k=sum_{k,m=1}^rS_{km}Z_{mj}e_k\ \
          &=sum_{m=1}^r Z_{mj}sum_{k=1}^rS_{km}e_k=sum_{m=1}^rZ_{mj}v_m\ \
          &=sum_{m=1}^rU_{jm}v_m,
          end{align}

          where $U=Z^T$.






          share|cite|improve this answer























          • By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
            – mathrookie
            Nov 22 at 21:06












          • If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
            – Martin Argerami
            Nov 22 at 22:15











          Your Answer





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          2 Answers
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          2 Answers
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          active

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          up vote
          2
          down vote













          I am not sure what purpose does your exercise serve, but the answer can be more succinct. Put together the vectors $v_i$s to form a matrix $V$ and define $W$ analogously. Then both $V$ and $W$ have full column ranks and $VV^ast=WW^ast$. Hence $V^ast x=0$ if and only if $W^ast x=0$, i.e. the column spaces of $V$ and $W$ have a common orthogonal complement $mathcal X$. Let $X$ be a matrix whose columns form a basis of $mathcal X$. Then both augmented matrices $[V|X]$ and $[W|X]$ are invertible. Since $VV^ast=WW^ast$, we get $[V|X][V|X]^ast = [W|X][W|X]^ast$. Thus $U=[W|X]^{-1}[V|X]$ is a unitary matrix and $V=WU$.






          share|cite|improve this answer























          • Very neat. $ $
            – Martin Argerami
            Nov 22 at 5:27















          up vote
          2
          down vote













          I am not sure what purpose does your exercise serve, but the answer can be more succinct. Put together the vectors $v_i$s to form a matrix $V$ and define $W$ analogously. Then both $V$ and $W$ have full column ranks and $VV^ast=WW^ast$. Hence $V^ast x=0$ if and only if $W^ast x=0$, i.e. the column spaces of $V$ and $W$ have a common orthogonal complement $mathcal X$. Let $X$ be a matrix whose columns form a basis of $mathcal X$. Then both augmented matrices $[V|X]$ and $[W|X]$ are invertible. Since $VV^ast=WW^ast$, we get $[V|X][V|X]^ast = [W|X][W|X]^ast$. Thus $U=[W|X]^{-1}[V|X]$ is a unitary matrix and $V=WU$.






          share|cite|improve this answer























          • Very neat. $ $
            – Martin Argerami
            Nov 22 at 5:27













          up vote
          2
          down vote










          up vote
          2
          down vote









          I am not sure what purpose does your exercise serve, but the answer can be more succinct. Put together the vectors $v_i$s to form a matrix $V$ and define $W$ analogously. Then both $V$ and $W$ have full column ranks and $VV^ast=WW^ast$. Hence $V^ast x=0$ if and only if $W^ast x=0$, i.e. the column spaces of $V$ and $W$ have a common orthogonal complement $mathcal X$. Let $X$ be a matrix whose columns form a basis of $mathcal X$. Then both augmented matrices $[V|X]$ and $[W|X]$ are invertible. Since $VV^ast=WW^ast$, we get $[V|X][V|X]^ast = [W|X][W|X]^ast$. Thus $U=[W|X]^{-1}[V|X]$ is a unitary matrix and $V=WU$.






          share|cite|improve this answer














          I am not sure what purpose does your exercise serve, but the answer can be more succinct. Put together the vectors $v_i$s to form a matrix $V$ and define $W$ analogously. Then both $V$ and $W$ have full column ranks and $VV^ast=WW^ast$. Hence $V^ast x=0$ if and only if $W^ast x=0$, i.e. the column spaces of $V$ and $W$ have a common orthogonal complement $mathcal X$. Let $X$ be a matrix whose columns form a basis of $mathcal X$. Then both augmented matrices $[V|X]$ and $[W|X]$ are invertible. Since $VV^ast=WW^ast$, we get $[V|X][V|X]^ast = [W|X][W|X]^ast$. Thus $U=[W|X]^{-1}[V|X]$ is a unitary matrix and $V=WU$.







          share|cite|improve this answer














          share|cite|improve this answer



          share|cite|improve this answer








          answered Nov 22 at 5:13


























          community wiki





          user1551













          • Very neat. $ $
            – Martin Argerami
            Nov 22 at 5:27


















          • Very neat. $ $
            – Martin Argerami
            Nov 22 at 5:27
















          Very neat. $ $
          – Martin Argerami
          Nov 22 at 5:27




          Very neat. $ $
          – Martin Argerami
          Nov 22 at 5:27










          up vote
          1
          down vote













          The relation is that there exists a unitary $Uin M_r(mathbb C)$ such that $$w_j=sum_{k=1}^r U_{jk}v_k.$$



          Indeed, fix an orthonormal basis $e_1,ldots,e_n$ of $mathbb C^n$, and we may write
          $$
          v_k=sum_{k=1}^ns_{jk}e_j, w_k=sum_{j=1}^rt_{jk}e_j.
          $$

          Now consider $S,Tin M_r(mathbb C)$ with $S_{kj}=s_{kj}$, $T_{kj}=t_{kj}$. Then
          $$
          P=sum_{k=1}^rv_kv_k^*=sum_{k=1}^rsum_{j,ell=1}^rs_{jk}overline{s_{ell k}}e_je_ell^*=sum_{k=1}^rsum_{j,ell=1}^rS_{jk}{(S^*)_{k ell}}e_je_ell^*=sum_{j,ell=1}^r(SS^*)_{jell}e_je_ell^*.
          $$

          Similarly,
          $$
          P=sum_{j,ell=1}^r(TT^*)_{jell}e_je_ell^*.
          $$

          As $e_je_ell^*$ are the matrix units in $M_r(mathbb C)$, we get that $TT^*=SS^*$. Now we write the polar decompositions
          $$
          S^*=W(SS^*)^{1/2}, T^*=V(TT^*)^{1/2},
          $$

          where $W,V$ are unitaries. Then $S=(SS^*)^{1/2}W^*$, and
          $$
          T=(TT^*)^{1/2}V^*=(SS^*)^{1/2}V^*=SWV^*=SZ,
          $$

          where $Z=WV^*$. Now
          begin{align}
          w_j&=sum_{k=1}^r t_{kj}e_k=sum_{k=1}^r(SZ)_{kj}e_k=sum_{k,m=1}^rS_{km}Z_{mj}e_k\ \
          &=sum_{m=1}^r Z_{mj}sum_{k=1}^rS_{km}e_k=sum_{m=1}^rZ_{mj}v_m\ \
          &=sum_{m=1}^rU_{jm}v_m,
          end{align}

          where $U=Z^T$.






          share|cite|improve this answer























          • By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
            – mathrookie
            Nov 22 at 21:06












          • If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
            – Martin Argerami
            Nov 22 at 22:15















          up vote
          1
          down vote













          The relation is that there exists a unitary $Uin M_r(mathbb C)$ such that $$w_j=sum_{k=1}^r U_{jk}v_k.$$



          Indeed, fix an orthonormal basis $e_1,ldots,e_n$ of $mathbb C^n$, and we may write
          $$
          v_k=sum_{k=1}^ns_{jk}e_j, w_k=sum_{j=1}^rt_{jk}e_j.
          $$

          Now consider $S,Tin M_r(mathbb C)$ with $S_{kj}=s_{kj}$, $T_{kj}=t_{kj}$. Then
          $$
          P=sum_{k=1}^rv_kv_k^*=sum_{k=1}^rsum_{j,ell=1}^rs_{jk}overline{s_{ell k}}e_je_ell^*=sum_{k=1}^rsum_{j,ell=1}^rS_{jk}{(S^*)_{k ell}}e_je_ell^*=sum_{j,ell=1}^r(SS^*)_{jell}e_je_ell^*.
          $$

          Similarly,
          $$
          P=sum_{j,ell=1}^r(TT^*)_{jell}e_je_ell^*.
          $$

          As $e_je_ell^*$ are the matrix units in $M_r(mathbb C)$, we get that $TT^*=SS^*$. Now we write the polar decompositions
          $$
          S^*=W(SS^*)^{1/2}, T^*=V(TT^*)^{1/2},
          $$

          where $W,V$ are unitaries. Then $S=(SS^*)^{1/2}W^*$, and
          $$
          T=(TT^*)^{1/2}V^*=(SS^*)^{1/2}V^*=SWV^*=SZ,
          $$

          where $Z=WV^*$. Now
          begin{align}
          w_j&=sum_{k=1}^r t_{kj}e_k=sum_{k=1}^r(SZ)_{kj}e_k=sum_{k,m=1}^rS_{km}Z_{mj}e_k\ \
          &=sum_{m=1}^r Z_{mj}sum_{k=1}^rS_{km}e_k=sum_{m=1}^rZ_{mj}v_m\ \
          &=sum_{m=1}^rU_{jm}v_m,
          end{align}

          where $U=Z^T$.






          share|cite|improve this answer























          • By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
            – mathrookie
            Nov 22 at 21:06












          • If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
            – Martin Argerami
            Nov 22 at 22:15













          up vote
          1
          down vote










          up vote
          1
          down vote









          The relation is that there exists a unitary $Uin M_r(mathbb C)$ such that $$w_j=sum_{k=1}^r U_{jk}v_k.$$



          Indeed, fix an orthonormal basis $e_1,ldots,e_n$ of $mathbb C^n$, and we may write
          $$
          v_k=sum_{k=1}^ns_{jk}e_j, w_k=sum_{j=1}^rt_{jk}e_j.
          $$

          Now consider $S,Tin M_r(mathbb C)$ with $S_{kj}=s_{kj}$, $T_{kj}=t_{kj}$. Then
          $$
          P=sum_{k=1}^rv_kv_k^*=sum_{k=1}^rsum_{j,ell=1}^rs_{jk}overline{s_{ell k}}e_je_ell^*=sum_{k=1}^rsum_{j,ell=1}^rS_{jk}{(S^*)_{k ell}}e_je_ell^*=sum_{j,ell=1}^r(SS^*)_{jell}e_je_ell^*.
          $$

          Similarly,
          $$
          P=sum_{j,ell=1}^r(TT^*)_{jell}e_je_ell^*.
          $$

          As $e_je_ell^*$ are the matrix units in $M_r(mathbb C)$, we get that $TT^*=SS^*$. Now we write the polar decompositions
          $$
          S^*=W(SS^*)^{1/2}, T^*=V(TT^*)^{1/2},
          $$

          where $W,V$ are unitaries. Then $S=(SS^*)^{1/2}W^*$, and
          $$
          T=(TT^*)^{1/2}V^*=(SS^*)^{1/2}V^*=SWV^*=SZ,
          $$

          where $Z=WV^*$. Now
          begin{align}
          w_j&=sum_{k=1}^r t_{kj}e_k=sum_{k=1}^r(SZ)_{kj}e_k=sum_{k,m=1}^rS_{km}Z_{mj}e_k\ \
          &=sum_{m=1}^r Z_{mj}sum_{k=1}^rS_{km}e_k=sum_{m=1}^rZ_{mj}v_m\ \
          &=sum_{m=1}^rU_{jm}v_m,
          end{align}

          where $U=Z^T$.






          share|cite|improve this answer














          The relation is that there exists a unitary $Uin M_r(mathbb C)$ such that $$w_j=sum_{k=1}^r U_{jk}v_k.$$



          Indeed, fix an orthonormal basis $e_1,ldots,e_n$ of $mathbb C^n$, and we may write
          $$
          v_k=sum_{k=1}^ns_{jk}e_j, w_k=sum_{j=1}^rt_{jk}e_j.
          $$

          Now consider $S,Tin M_r(mathbb C)$ with $S_{kj}=s_{kj}$, $T_{kj}=t_{kj}$. Then
          $$
          P=sum_{k=1}^rv_kv_k^*=sum_{k=1}^rsum_{j,ell=1}^rs_{jk}overline{s_{ell k}}e_je_ell^*=sum_{k=1}^rsum_{j,ell=1}^rS_{jk}{(S^*)_{k ell}}e_je_ell^*=sum_{j,ell=1}^r(SS^*)_{jell}e_je_ell^*.
          $$

          Similarly,
          $$
          P=sum_{j,ell=1}^r(TT^*)_{jell}e_je_ell^*.
          $$

          As $e_je_ell^*$ are the matrix units in $M_r(mathbb C)$, we get that $TT^*=SS^*$. Now we write the polar decompositions
          $$
          S^*=W(SS^*)^{1/2}, T^*=V(TT^*)^{1/2},
          $$

          where $W,V$ are unitaries. Then $S=(SS^*)^{1/2}W^*$, and
          $$
          T=(TT^*)^{1/2}V^*=(SS^*)^{1/2}V^*=SWV^*=SZ,
          $$

          where $Z=WV^*$. Now
          begin{align}
          w_j&=sum_{k=1}^r t_{kj}e_k=sum_{k=1}^r(SZ)_{kj}e_k=sum_{k,m=1}^rS_{km}Z_{mj}e_k\ \
          &=sum_{m=1}^r Z_{mj}sum_{k=1}^rS_{km}e_k=sum_{m=1}^rZ_{mj}v_m\ \
          &=sum_{m=1}^rU_{jm}v_m,
          end{align}

          where $U=Z^T$.







          share|cite|improve this answer














          share|cite|improve this answer



          share|cite|improve this answer








          edited Nov 22 at 13:34

























          answered Nov 22 at 4:20









          Martin Argerami

          123k1176174




          123k1176174












          • By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
            – mathrookie
            Nov 22 at 21:06












          • If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
            – Martin Argerami
            Nov 22 at 22:15


















          • By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
            – mathrookie
            Nov 22 at 21:06












          • If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
            – Martin Argerami
            Nov 22 at 22:15
















          By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
          – mathrookie
          Nov 22 at 21:06






          By polar decomposition,we have $W,V$ are partial isometries,why are they unitaries?Besides,the other reprentation of $P$ may have $m(m>r)$ sum of rank 1 matrices.
          – mathrookie
          Nov 22 at 21:06














          If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
          – Martin Argerami
          Nov 22 at 22:15




          If you do the polar decomposition in $M_r(mathbb C)$, you can always take them to be unitaries. As for $m>r$, enlarge the smallest family with zeroes.
          – Martin Argerami
          Nov 22 at 22:15


















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