Attaining the norm of a C*-algebra quotient by an ideal
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The following statement is Exercise I.26 in K. Davidson's book C-Algebras by Example*:
Let $mathfrak{A}$ be a C*-algebra, $mathfrak{J}$ be an (two-sided
and closed) ideal of $mathfrak{A}$ and $A in mathfrak{A}$. Then
there exists $J in mathfrak{J}$ such that $|A - J| = |A + mathfrak{J}|$.
The book gives a hint of applying the Jordan decomposition (Corollary I.4.2 in the book) of the element $|A|-|A+mathfrak{J}|I$. But I don't see how to proceed from here. Any help would be appreciated. Thank you!
operator-algebras c-star-algebras
asked 18 hours ago
Ken Leung
8816
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2
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The following statement is Exercise I.26 in K. Davidson's book C-Algebras by Example*:
Let $mathfrak{A}$ be a C*-algebra, $mathfrak{J}$ be an (two-sided
and closed) ideal of $mathfrak{A}$ and $A in mathfrak{A}$. Then
there exists $J in mathfrak{J}$ such that $|A - J| = |A + mathfrak{J}|$.
The book gives a hint of applying the Jordan decomposition (Corollary I.4.2 in the book) of the element $|A|-|A+mathfrak{J}|I$. But I don't see how to proceed from here. Any help would be appreciated. Thank you!
operator-algebras c-star-algebras
asked 18 hours ago
Ken Leung
8816
add a comment |
up vote
2
down vote
favorite
up vote
2
down vote
favorite
The following statement is Exercise I.26 in K. Davidson's book C-Algebras by Example*:
Let $mathfrak{A}$ be a C*-algebra, $mathfrak{J}$ be an (two-sided
and closed) ideal of $mathfrak{A}$ and $A in mathfrak{A}$. Then
there exists $J in mathfrak{J}$ such that $|A - J| = |A + mathfrak{J}|$.
The book gives a hint of applying the Jordan decomposition (Corollary I.4.2 in the book) of the element $|A|-|A+mathfrak{J}|I$. But I don't see how to proceed from here. Any help would be appreciated. Thank you!
operator-algebras c-star-algebras
asked 18 hours ago
Ken Leung
8816
The following statement is Exercise I.26 in K. Davidson's book C-Algebras by Example*:
Let $mathfrak{A}$ be a C*-algebra, $mathfrak{J}$ be an (two-sided
and closed) ideal of $mathfrak{A}$ and $A in mathfrak{A}$. Then
there exists $J in mathfrak{J}$ such that $|A - J| = |A + mathfrak{J}|$.
The book gives a hint of applying the Jordan decomposition (Corollary I.4.2 in the book) of the element $|A|-|A+mathfrak{J}|I$. But I don't see how to proceed from here. Any help would be appreciated. Thank you!
operator-algebras c-star-algebras
operator-algebras c-star-algebras
asked 18 hours ago
Ken Leung
8816
asked 18 hours ago
Ken Leung
8816
asked 18 hours ago
Ken Leung
8816
asked 18 hours ago
Ken Leung
8816
asked 18 hours ago
Ken Leung
8816
8816
add a comment |
add a comment |
1 Answer
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I'll be happy to be proven wrong and see a proof using the Jordan decomposition. But I'm guessing that there is a typo in the book and that the intent was to say "Corollary I.5.6".
Assume first that $A=C(T)$ for some compact Hausdorff $T$. Then $J={f: f|_E=0}$ for some compact $Esubset T$. Fix $fin C(T)$. As $T$ is compact, there exists $t_0in T$ with $|f|=|f(t_0)|$.
If $t_0in E$, then $|f-g|geq|f(t_0)|=|f|$ for any $gin J$; then $|f+J|=|f|=|f-0|$.
If $t_0notin E$, we may use Urysohn's Lemma to construct $gin C(T)$ with $g|_E=0$, $g(t_0)=|f|-|f+J|$, and $|g|leq g(t_0)$. Then $$|f-g|geq|f(t_0)-g(t_0)|=|f+J|,$$
so $|f+J|=|f-g|$.
Now consider the general case. By Corollary I.5.6,
$$tag1
frac{C^*(a)}{C^*(a)cap J}simeq frac{C^*(a)+J}{J}.
$$
So, as the isomorphism is canonical and, of course, isometric,
$$
|a+J|=|a+C^*(a)cap J|,
$$
where the second quotient norm happens in an abelian C$^*$-algebra from the left in $(1)$. From the abelian case above, there exists $bin C^*(a)cap J$ with $|a-b|=|a+C^*(a)cap J|geq|a+J|$. Thus
$$
|a-b|=|a+J|.
$$
answered 3 hours ago
Martin Argerami
120k1072170
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1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
1
down vote
accepted
I'll be happy to be proven wrong and see a proof using the Jordan decomposition. But I'm guessing that there is a typo in the book and that the intent was to say "Corollary I.5.6".
Assume first that $A=C(T)$ for some compact Hausdorff $T$. Then $J={f: f|_E=0}$ for some compact $Esubset T$. Fix $fin C(T)$. As $T$ is compact, there exists $t_0in T$ with $|f|=|f(t_0)|$.
If $t_0in E$, then $|f-g|geq|f(t_0)|=|f|$ for any $gin J$; then $|f+J|=|f|=|f-0|$.
If $t_0notin E$, we may use Urysohn's Lemma to construct $gin C(T)$ with $g|_E=0$, $g(t_0)=|f|-|f+J|$, and $|g|leq g(t_0)$. Then $$|f-g|geq|f(t_0)-g(t_0)|=|f+J|,$$
so $|f+J|=|f-g|$.
Now consider the general case. By Corollary I.5.6,
$$tag1
frac{C^*(a)}{C^*(a)cap J}simeq frac{C^*(a)+J}{J}.
$$
So, as the isomorphism is canonical and, of course, isometric,
$$
|a+J|=|a+C^*(a)cap J|,
$$
where the second quotient norm happens in an abelian C$^*$-algebra from the left in $(1)$. From the abelian case above, there exists $bin C^*(a)cap J$ with $|a-b|=|a+C^*(a)cap J|geq|a+J|$. Thus
$$
|a-b|=|a+J|.
$$
answered 3 hours ago
Martin Argerami
120k1072170
add a comment |
up vote
1
down vote
accepted
I'll be happy to be proven wrong and see a proof using the Jordan decomposition. But I'm guessing that there is a typo in the book and that the intent was to say "Corollary I.5.6".
Assume first that $A=C(T)$ for some compact Hausdorff $T$. Then $J={f: f|_E=0}$ for some compact $Esubset T$. Fix $fin C(T)$. As $T$ is compact, there exists $t_0in T$ with $|f|=|f(t_0)|$.
If $t_0in E$, then $|f-g|geq|f(t_0)|=|f|$ for any $gin J$; then $|f+J|=|f|=|f-0|$.
If $t_0notin E$, we may use Urysohn's Lemma to construct $gin C(T)$ with $g|_E=0$, $g(t_0)=|f|-|f+J|$, and $|g|leq g(t_0)$. Then $$|f-g|geq|f(t_0)-g(t_0)|=|f+J|,$$
so $|f+J|=|f-g|$.
Now consider the general case. By Corollary I.5.6,
$$tag1
frac{C^*(a)}{C^*(a)cap J}simeq frac{C^*(a)+J}{J}.
$$
So, as the isomorphism is canonical and, of course, isometric,
$$
|a+J|=|a+C^*(a)cap J|,
$$
where the second quotient norm happens in an abelian C$^*$-algebra from the left in $(1)$. From the abelian case above, there exists $bin C^*(a)cap J$ with $|a-b|=|a+C^*(a)cap J|geq|a+J|$. Thus
$$
|a-b|=|a+J|.
$$
answered 3 hours ago
Martin Argerami
120k1072170
add a comment |
up vote
1
down vote
accepted
up vote
1
down vote
accepted
I'll be happy to be proven wrong and see a proof using the Jordan decomposition. But I'm guessing that there is a typo in the book and that the intent was to say "Corollary I.5.6".
Assume first that $A=C(T)$ for some compact Hausdorff $T$. Then $J={f: f|_E=0}$ for some compact $Esubset T$. Fix $fin C(T)$. As $T$ is compact, there exists $t_0in T$ with $|f|=|f(t_0)|$.
If $t_0in E$, then $|f-g|geq|f(t_0)|=|f|$ for any $gin J$; then $|f+J|=|f|=|f-0|$.
If $t_0notin E$, we may use Urysohn's Lemma to construct $gin C(T)$ with $g|_E=0$, $g(t_0)=|f|-|f+J|$, and $|g|leq g(t_0)$. Then $$|f-g|geq|f(t_0)-g(t_0)|=|f+J|,$$
so $|f+J|=|f-g|$.
Now consider the general case. By Corollary I.5.6,
$$tag1
frac{C^*(a)}{C^*(a)cap J}simeq frac{C^*(a)+J}{J}.
$$
So, as the isomorphism is canonical and, of course, isometric,
$$
|a+J|=|a+C^*(a)cap J|,
$$
where the second quotient norm happens in an abelian C$^*$-algebra from the left in $(1)$. From the abelian case above, there exists $bin C^*(a)cap J$ with $|a-b|=|a+C^*(a)cap J|geq|a+J|$. Thus
$$
|a-b|=|a+J|.
$$
answered 3 hours ago
Martin Argerami
120k1072170
I'll be happy to be proven wrong and see a proof using the Jordan decomposition. But I'm guessing that there is a typo in the book and that the intent was to say "Corollary I.5.6".
Assume first that $A=C(T)$ for some compact Hausdorff $T$. Then $J={f: f|_E=0}$ for some compact $Esubset T$. Fix $fin C(T)$. As $T$ is compact, there exists $t_0in T$ with $|f|=|f(t_0)|$.
If $t_0in E$, then $|f-g|geq|f(t_0)|=|f|$ for any $gin J$; then $|f+J|=|f|=|f-0|$.
If $t_0notin E$, we may use Urysohn's Lemma to construct $gin C(T)$ with $g|_E=0$, $g(t_0)=|f|-|f+J|$, and $|g|leq g(t_0)$. Then $$|f-g|geq|f(t_0)-g(t_0)|=|f+J|,$$
so $|f+J|=|f-g|$.
Now consider the general case. By Corollary I.5.6,
$$tag1
frac{C^*(a)}{C^*(a)cap J}simeq frac{C^*(a)+J}{J}.
$$
So, as the isomorphism is canonical and, of course, isometric,
$$
|a+J|=|a+C^*(a)cap J|,
$$
where the second quotient norm happens in an abelian C$^*$-algebra from the left in $(1)$. From the abelian case above, there exists $bin C^*(a)cap J$ with $|a-b|=|a+C^*(a)cap J|geq|a+J|$. Thus
$$
|a-b|=|a+J|.
$$
answered 3 hours ago
Martin Argerami
120k1072170
answered 3 hours ago
Martin Argerami
120k1072170
answered 3 hours ago
Martin Argerami
120k1072170
answered 3 hours ago
Martin Argerami
120k1072170
120k1072170
add a comment |
add a comment |
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