Why does $mathscrP_2$ being isomorphic to $R^3$ imply that a constantwise addition of objects in $mathscrP_2$ is an inner product? The Next CEO of Stack OverflowWhat does inner product actually mean?Prove that $langle v,w rangle = (Abf v) cdot (Abf w)$ defines an inner product on $mathbbR^m$ iff $ker(A)=bf 0$Prove that there is a unique inner product on $V$Relationship between isomorphic vector spaces and inner productWhat does it mean for an inner product to be conjugate linear in the second entry?How does changing an inner product change the angle between two vectors?Showing that this inner product equality holdsWhy is inner product denoted like this?Isomorphic as inner product spacesWith these definitions how do I prove that this inner product is positive-definite?
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Why does $mathscrP_2$ being isomorphic to $R^3$ imply that a constantwise addition of objects in $mathscrP_2$ is an inner product?
The Next CEO of Stack OverflowWhat does inner product actually mean?Prove that $langle v,w rangle = (Abf v) cdot (Abf w)$ defines an inner product on $mathbbR^m$ iff $ker(A)=bf 0$Prove that there is a unique inner product on $V$Relationship between isomorphic vector spaces and inner productWhat does it mean for an inner product to be conjugate linear in the second entry?How does changing an inner product change the angle between two vectors?Showing that this inner product equality holdsWhy is inner product denoted like this?Isomorphic as inner product spacesWith these definitions how do I prove that this inner product is positive-definite?
$begingroup$
Why does saying that $mathscrP_2$ is isomorphic to $R^3$ immediately prove that a constant-wise addition of objects in $mathscrP_2$ is an inner product?
What I mean by constant-wise addition is this operation:
let $p(x) = a+bx+cx^2$ and let $q(x) = d + ex + fx^2$. The operation in question is: $langle p(x),q(x)rangle = ad + be + cf $
To show that that operation is an inner product on $mathscrP_2$, we need only show that the dot product in $R^3$ is an inner product, because $mathscrP_2$ is isomorphic to $R^3$ (and the dot product is indeed an inner product on $R^2$).
Why is that? What significance does $mathscrP_2$ being isomorphic to $R^3$ have in this context?
linear-algebra vector-spaces inner-product-space vector-space-isomorphism
edited Mar 27 at 19:19
MPW
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
$endgroup$
add a comment |
$begingroup$
Why does saying that $mathscrP_2$ is isomorphic to $R^3$ immediately prove that a constant-wise addition of objects in $mathscrP_2$ is an inner product?
What I mean by constant-wise addition is this operation:
let $p(x) = a+bx+cx^2$ and let $q(x) = d + ex + fx^2$. The operation in question is: $langle p(x),q(x)rangle = ad + be + cf $
To show that that operation is an inner product on $mathscrP_2$, we need only show that the dot product in $R^3$ is an inner product, because $mathscrP_2$ is isomorphic to $R^3$ (and the dot product is indeed an inner product on $R^2$).
Why is that? What significance does $mathscrP_2$ being isomorphic to $R^3$ have in this context?
linear-algebra vector-spaces inner-product-space vector-space-isomorphism
edited Mar 27 at 19:19
MPW
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
$endgroup$
add a comment |
$begingroup$
Why does saying that $mathscrP_2$ is isomorphic to $R^3$ immediately prove that a constant-wise addition of objects in $mathscrP_2$ is an inner product?
What I mean by constant-wise addition is this operation:
let $p(x) = a+bx+cx^2$ and let $q(x) = d + ex + fx^2$. The operation in question is: $langle p(x),q(x)rangle = ad + be + cf $
To show that that operation is an inner product on $mathscrP_2$, we need only show that the dot product in $R^3$ is an inner product, because $mathscrP_2$ is isomorphic to $R^3$ (and the dot product is indeed an inner product on $R^2$).
Why is that? What significance does $mathscrP_2$ being isomorphic to $R^3$ have in this context?
linear-algebra vector-spaces inner-product-space vector-space-isomorphism
edited Mar 27 at 19:19
MPW
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
$endgroup$
Why does saying that $mathscrP_2$ is isomorphic to $R^3$ immediately prove that a constant-wise addition of objects in $mathscrP_2$ is an inner product?
What I mean by constant-wise addition is this operation:
let $p(x) = a+bx+cx^2$ and let $q(x) = d + ex + fx^2$. The operation in question is: $langle p(x),q(x)rangle = ad + be + cf $
To show that that operation is an inner product on $mathscrP_2$, we need only show that the dot product in $R^3$ is an inner product, because $mathscrP_2$ is isomorphic to $R^3$ (and the dot product is indeed an inner product on $R^2$).
Why is that? What significance does $mathscrP_2$ being isomorphic to $R^3$ have in this context?
linear-algebra vector-spaces inner-product-space vector-space-isomorphism
linear-algebra vector-spaces inner-product-space vector-space-isomorphism
edited Mar 27 at 19:19
MPW
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
edited Mar 27 at 19:19
MPW
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
edited Mar 27 at 19:19
MPW
31k12157
edited Mar 27 at 19:19
MPW
31k12157
edited Mar 27 at 19:19
MPW
31k12157
31k12157
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
asked Mar 27 at 19:17
Nest Doberman Nest Doberman
311
311
add a comment |
add a comment |
1 Answer
1
active
oldest
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$begingroup$
Let $phi: mathscr P_2 to Bbb R^3$ be the isomorphism of vector spaces given by $phi(a + bx + cx^2) = (a,b,c)$. Let $langle cdot, cdot rangle_Bbb R^3 : Bbb R^3 times Bbb R^3 to Bbb R$ denote the usual dot-product. Your "constant-wise addition" can be written as the map $( cdot , cdot): mathscr P_2 times mathscr P_2 to Bbb R$ defined by
$$
(p,q) = langle phi(p), phi(q) rangle_Bbb R^3 qquad p,q in mathscr P_2.
$$
Using the fact that $phi$ is an isomorphism of vector spaces (an invertible linear transformation) and that $langle cdot, cdot rangle_Bbb R^3$ is an inner-product, we can show that $( cdot , cdot)$ as defined above satisfies the definition of an inner product.
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
$endgroup$
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
add a comment |
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1 Answer
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1 Answer
1
active
oldest
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active
oldest
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active
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votes
$begingroup$
Let $phi: mathscr P_2 to Bbb R^3$ be the isomorphism of vector spaces given by $phi(a + bx + cx^2) = (a,b,c)$. Let $langle cdot, cdot rangle_Bbb R^3 : Bbb R^3 times Bbb R^3 to Bbb R$ denote the usual dot-product. Your "constant-wise addition" can be written as the map $( cdot , cdot): mathscr P_2 times mathscr P_2 to Bbb R$ defined by
$$
(p,q) = langle phi(p), phi(q) rangle_Bbb R^3 qquad p,q in mathscr P_2.
$$
Using the fact that $phi$ is an isomorphism of vector spaces (an invertible linear transformation) and that $langle cdot, cdot rangle_Bbb R^3$ is an inner-product, we can show that $( cdot , cdot)$ as defined above satisfies the definition of an inner product.
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
$endgroup$
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
add a comment |
$begingroup$
Let $phi: mathscr P_2 to Bbb R^3$ be the isomorphism of vector spaces given by $phi(a + bx + cx^2) = (a,b,c)$. Let $langle cdot, cdot rangle_Bbb R^3 : Bbb R^3 times Bbb R^3 to Bbb R$ denote the usual dot-product. Your "constant-wise addition" can be written as the map $( cdot , cdot): mathscr P_2 times mathscr P_2 to Bbb R$ defined by
$$
(p,q) = langle phi(p), phi(q) rangle_Bbb R^3 qquad p,q in mathscr P_2.
$$
Using the fact that $phi$ is an isomorphism of vector spaces (an invertible linear transformation) and that $langle cdot, cdot rangle_Bbb R^3$ is an inner-product, we can show that $( cdot , cdot)$ as defined above satisfies the definition of an inner product.
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
$endgroup$
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
add a comment |
$begingroup$
Let $phi: mathscr P_2 to Bbb R^3$ be the isomorphism of vector spaces given by $phi(a + bx + cx^2) = (a,b,c)$. Let $langle cdot, cdot rangle_Bbb R^3 : Bbb R^3 times Bbb R^3 to Bbb R$ denote the usual dot-product. Your "constant-wise addition" can be written as the map $( cdot , cdot): mathscr P_2 times mathscr P_2 to Bbb R$ defined by
$$
(p,q) = langle phi(p), phi(q) rangle_Bbb R^3 qquad p,q in mathscr P_2.
$$
Using the fact that $phi$ is an isomorphism of vector spaces (an invertible linear transformation) and that $langle cdot, cdot rangle_Bbb R^3$ is an inner-product, we can show that $( cdot , cdot)$ as defined above satisfies the definition of an inner product.
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
$endgroup$
Let $phi: mathscr P_2 to Bbb R^3$ be the isomorphism of vector spaces given by $phi(a + bx + cx^2) = (a,b,c)$. Let $langle cdot, cdot rangle_Bbb R^3 : Bbb R^3 times Bbb R^3 to Bbb R$ denote the usual dot-product. Your "constant-wise addition" can be written as the map $( cdot , cdot): mathscr P_2 times mathscr P_2 to Bbb R$ defined by
$$
(p,q) = langle phi(p), phi(q) rangle_Bbb R^3 qquad p,q in mathscr P_2.
$$
Using the fact that $phi$ is an isomorphism of vector spaces (an invertible linear transformation) and that $langle cdot, cdot rangle_Bbb R^3$ is an inner-product, we can show that $( cdot , cdot)$ as defined above satisfies the definition of an inner product.
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
edited yesterday
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
answered Mar 27 at 19:38
OmnomnomnomOmnomnomnom
129k792186
129k792186
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
add a comment |
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
Sorry for the late response, thank you very much for the help! This makes sense, just one question: you say "we can show that...". Are you saying that a proof follows from the isomorphism and dot product you described, or are you saying that the presence of those two things is the proof? Nonetheless, thinking of it while keeping that isomorphism in mind makes it much more intuitive, thanks again!
$endgroup$
– Nest Doberman
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
$begingroup$
@NestDoberman I'm saying that there is a proof that $(cdot, cdot)$ is an inner product that uses only the fact that $phi$ is an isomorphism and $langle cdot , cdot rangle_Bbb R^3$ is an inner product. You're welcome
$endgroup$
– Omnomnomnom
yesterday
add a comment |
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