A Hahn-Banach separation theorem argument, claryfying the details
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I have a question regarding the proof of proposition 6.1. in https://arxiv.org/pdf/1509.01870.pdf, how exactly Hahn-Banach separation theorem has been used.
Proposition 6.1: A discrete group is $C^*$-simple iff for every bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ and every $ain C_r^*(G)$ $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|=0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$.
Proof: By a result stated in the paper, $G$ is not $C^*$-simple if and only if there is a bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ such that $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$. By the Hahn-Banach separation theorem, this is equivalent to the existence of $ain C_r^*(G)$ such that $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|>0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$. (QED)
Note that ${lambda_galambda_{g^{-1}}mid gin G}$ is the G-orbit of $a$ in $C_r^*(G)$.
It's clear to me that if $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$, that the functionals must have strictly positive disctance somewhere. But how precisly is that Hahn-Banach's separation theorem? I see it is applied to the convex disjoint sets A={the weak* closed convex hull of the orbit $Gphi$} and $B={phi(1)tau_lambda}$ right? But then there must be a functional which seperated $A$ and $B$. And here it doesn't look to me as an application of Hahn-Banach.
functional-analysis operator-algebras c-star-algebras
asked 14 hours ago
toto
471212
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I have a question regarding the proof of proposition 6.1. in https://arxiv.org/pdf/1509.01870.pdf, how exactly Hahn-Banach separation theorem has been used.
Proposition 6.1: A discrete group is $C^*$-simple iff for every bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ and every $ain C_r^*(G)$ $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|=0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$.
Proof: By a result stated in the paper, $G$ is not $C^*$-simple if and only if there is a bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ such that $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$. By the Hahn-Banach separation theorem, this is equivalent to the existence of $ain C_r^*(G)$ such that $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|>0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$. (QED)
Note that ${lambda_galambda_{g^{-1}}mid gin G}$ is the G-orbit of $a$ in $C_r^*(G)$.
It's clear to me that if $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$, that the functionals must have strictly positive disctance somewhere. But how precisly is that Hahn-Banach's separation theorem? I see it is applied to the convex disjoint sets A={the weak* closed convex hull of the orbit $Gphi$} and $B={phi(1)tau_lambda}$ right? But then there must be a functional which seperated $A$ and $B$. And here it doesn't look to me as an application of Hahn-Banach.
functional-analysis operator-algebras c-star-algebras
asked 14 hours ago
toto
471212
add a comment |
up vote
1
down vote
favorite
up vote
1
down vote
favorite
I have a question regarding the proof of proposition 6.1. in https://arxiv.org/pdf/1509.01870.pdf, how exactly Hahn-Banach separation theorem has been used.
Proposition 6.1: A discrete group is $C^*$-simple iff for every bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ and every $ain C_r^*(G)$ $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|=0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$.
Proof: By a result stated in the paper, $G$ is not $C^*$-simple if and only if there is a bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ such that $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$. By the Hahn-Banach separation theorem, this is equivalent to the existence of $ain C_r^*(G)$ such that $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|>0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$. (QED)
Note that ${lambda_galambda_{g^{-1}}mid gin G}$ is the G-orbit of $a$ in $C_r^*(G)$.
It's clear to me that if $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$, that the functionals must have strictly positive disctance somewhere. But how precisly is that Hahn-Banach's separation theorem? I see it is applied to the convex disjoint sets A={the weak* closed convex hull of the orbit $Gphi$} and $B={phi(1)tau_lambda}$ right? But then there must be a functional which seperated $A$ and $B$. And here it doesn't look to me as an application of Hahn-Banach.
functional-analysis operator-algebras c-star-algebras
asked 14 hours ago
toto
471212
I have a question regarding the proof of proposition 6.1. in https://arxiv.org/pdf/1509.01870.pdf, how exactly Hahn-Banach separation theorem has been used.
Proposition 6.1: A discrete group is $C^*$-simple iff for every bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ and every $ain C_r^*(G)$ $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|=0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$.
Proof: By a result stated in the paper, $G$ is not $C^*$-simple if and only if there is a bounded linear functional $phicolon C_r^*(G)tomathbb{C}$ such that $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$. By the Hahn-Banach separation theorem, this is equivalent to the existence of $ain C_r^*(G)$ such that $$inf_{bin K}|phi(b)-phi(1)tau_{lambda}(a)|>0,$$ where $K$ denotes the norm closed conex hull of ${lambda_galambda_{g^{-1}}mid gin G}$. (QED)
Note that ${lambda_galambda_{g^{-1}}mid gin G}$ is the G-orbit of $a$ in $C_r^*(G)$.
It's clear to me that if $phi(1)tau_lambda$ does not belong to the weak* closed convex hull of the orbit $Gphi$, that the functionals must have strictly positive disctance somewhere. But how precisly is that Hahn-Banach's separation theorem? I see it is applied to the convex disjoint sets A={the weak* closed convex hull of the orbit $Gphi$} and $B={phi(1)tau_lambda}$ right? But then there must be a functional which seperated $A$ and $B$. And here it doesn't look to me as an application of Hahn-Banach.
functional-analysis operator-algebras c-star-algebras
functional-analysis operator-algebras c-star-algebras
asked 14 hours ago
toto
471212
asked 14 hours ago
toto
471212
asked 14 hours ago
toto
471212
asked 14 hours ago
toto
471212
asked 14 hours ago
toto
471212
471212
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1 Answer
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Let $A := C^*_r(G)$. Equip $A^*$, the topological dual of $A$, with the weak*-topology. Let us denote, as you already did,
$$
K := overline{mathrm{co}}^{w*}(Gphi), qquad F := {phi(1)tau_lambda}.
$$
Then, as you noted, by Hahn-Banach you find a continuous functional
$$
varphi in (A^*,text{weak*})^*,
$$
which separates $K$ and $F$. Now, the crucial point is that $varphi$ is given by some point evaluation, where we use that $A^*$ is equipped with the weak*-topology.
That gives you the required $a$, which does the job. Furthermore, one has to note that the weak* closure of a convex set in a normed space equals its norm-closure, which again invokes Hahn-Banach.
answered 13 hours ago
André S.
1,967314
add a comment |
1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
2
down vote
accepted
Let $A := C^*_r(G)$. Equip $A^*$, the topological dual of $A$, with the weak*-topology. Let us denote, as you already did,
$$
K := overline{mathrm{co}}^{w*}(Gphi), qquad F := {phi(1)tau_lambda}.
$$
Then, as you noted, by Hahn-Banach you find a continuous functional
$$
varphi in (A^*,text{weak*})^*,
$$
which separates $K$ and $F$. Now, the crucial point is that $varphi$ is given by some point evaluation, where we use that $A^*$ is equipped with the weak*-topology.
That gives you the required $a$, which does the job. Furthermore, one has to note that the weak* closure of a convex set in a normed space equals its norm-closure, which again invokes Hahn-Banach.
answered 13 hours ago
André S.
1,967314
add a comment |
up vote
2
down vote
accepted
Let $A := C^*_r(G)$. Equip $A^*$, the topological dual of $A$, with the weak*-topology. Let us denote, as you already did,
$$
K := overline{mathrm{co}}^{w*}(Gphi), qquad F := {phi(1)tau_lambda}.
$$
Then, as you noted, by Hahn-Banach you find a continuous functional
$$
varphi in (A^*,text{weak*})^*,
$$
which separates $K$ and $F$. Now, the crucial point is that $varphi$ is given by some point evaluation, where we use that $A^*$ is equipped with the weak*-topology.
That gives you the required $a$, which does the job. Furthermore, one has to note that the weak* closure of a convex set in a normed space equals its norm-closure, which again invokes Hahn-Banach.
answered 13 hours ago
André S.
1,967314
add a comment |
up vote
2
down vote
accepted
up vote
2
down vote
accepted
Let $A := C^*_r(G)$. Equip $A^*$, the topological dual of $A$, with the weak*-topology. Let us denote, as you already did,
$$
K := overline{mathrm{co}}^{w*}(Gphi), qquad F := {phi(1)tau_lambda}.
$$
Then, as you noted, by Hahn-Banach you find a continuous functional
$$
varphi in (A^*,text{weak*})^*,
$$
which separates $K$ and $F$. Now, the crucial point is that $varphi$ is given by some point evaluation, where we use that $A^*$ is equipped with the weak*-topology.
That gives you the required $a$, which does the job. Furthermore, one has to note that the weak* closure of a convex set in a normed space equals its norm-closure, which again invokes Hahn-Banach.
answered 13 hours ago
André S.
1,967314
Let $A := C^*_r(G)$. Equip $A^*$, the topological dual of $A$, with the weak*-topology. Let us denote, as you already did,
$$
K := overline{mathrm{co}}^{w*}(Gphi), qquad F := {phi(1)tau_lambda}.
$$
Then, as you noted, by Hahn-Banach you find a continuous functional
$$
varphi in (A^*,text{weak*})^*,
$$
which separates $K$ and $F$. Now, the crucial point is that $varphi$ is given by some point evaluation, where we use that $A^*$ is equipped with the weak*-topology.
That gives you the required $a$, which does the job. Furthermore, one has to note that the weak* closure of a convex set in a normed space equals its norm-closure, which again invokes Hahn-Banach.
answered 13 hours ago
André S.
1,967314
answered 13 hours ago
André S.
1,967314
answered 13 hours ago
André S.
1,967314
answered 13 hours ago
André S.
1,967314
1,967314
add a comment |
add a comment |
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