A doubt from the paper “Newton-Okounkov bodies, semigroups of integral points, graded algebras and...












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$begingroup$


I am currently reading the paper "Newton-Okounkov bodies, semigroups of integral points, graded algebras and intersection theory" by Kiumars Kaveh, Askold Georgievich Khovanskii (paper). In the page 937 the following paragraph appears:



Let $L$ be a linear subspace in $mathbb{R}^n$ and $M$ a half-space in $L$ with boundary $partial M$. A half-space $M subset L$ is rational if the subspaces $L$ and $partial M$ can be spanned by integral vectors, i.e., are rational subspaces.



$hspace{5mm}$ With a rational half-space $M subset L$ one can associate $partial M_{mathbb{Z}} = partial M capmathbb{Z}^n$ and $L_{mathbb{Z}} = L cap mathbb{Z}^n$. Take the linear map $pi_M : L rightarrow mathbb{R}$ such that $ker(pi_M) = partial M$, $pi_M(L_{mathbb{Z}}) = Z$ and $pi_M(M cap mathbb{Z}^n) = mathbb{Z}_{geq 0}$, the set of all nonnegative integers. The
linear map $pi_M$ induces an isomorphism from $L_{mathbb{Z}}/partial M_{mathbb{Z}}$ to $mathbb{Z}$.



I have the following question:



Q) Why the linear map $pi_M$ exists?



Thanks in advance.










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$endgroup$












  • $begingroup$
    Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
    $endgroup$
    – KReiser
    Dec 28 '18 at 9:25
















0












$begingroup$


I am currently reading the paper "Newton-Okounkov bodies, semigroups of integral points, graded algebras and intersection theory" by Kiumars Kaveh, Askold Georgievich Khovanskii (paper). In the page 937 the following paragraph appears:



Let $L$ be a linear subspace in $mathbb{R}^n$ and $M$ a half-space in $L$ with boundary $partial M$. A half-space $M subset L$ is rational if the subspaces $L$ and $partial M$ can be spanned by integral vectors, i.e., are rational subspaces.



$hspace{5mm}$ With a rational half-space $M subset L$ one can associate $partial M_{mathbb{Z}} = partial M capmathbb{Z}^n$ and $L_{mathbb{Z}} = L cap mathbb{Z}^n$. Take the linear map $pi_M : L rightarrow mathbb{R}$ such that $ker(pi_M) = partial M$, $pi_M(L_{mathbb{Z}}) = Z$ and $pi_M(M cap mathbb{Z}^n) = mathbb{Z}_{geq 0}$, the set of all nonnegative integers. The
linear map $pi_M$ induces an isomorphism from $L_{mathbb{Z}}/partial M_{mathbb{Z}}$ to $mathbb{Z}$.



I have the following question:



Q) Why the linear map $pi_M$ exists?



Thanks in advance.










share|cite|improve this question











$endgroup$












  • $begingroup$
    Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
    $endgroup$
    – KReiser
    Dec 28 '18 at 9:25














0












0








0





$begingroup$


I am currently reading the paper "Newton-Okounkov bodies, semigroups of integral points, graded algebras and intersection theory" by Kiumars Kaveh, Askold Georgievich Khovanskii (paper). In the page 937 the following paragraph appears:



Let $L$ be a linear subspace in $mathbb{R}^n$ and $M$ a half-space in $L$ with boundary $partial M$. A half-space $M subset L$ is rational if the subspaces $L$ and $partial M$ can be spanned by integral vectors, i.e., are rational subspaces.



$hspace{5mm}$ With a rational half-space $M subset L$ one can associate $partial M_{mathbb{Z}} = partial M capmathbb{Z}^n$ and $L_{mathbb{Z}} = L cap mathbb{Z}^n$. Take the linear map $pi_M : L rightarrow mathbb{R}$ such that $ker(pi_M) = partial M$, $pi_M(L_{mathbb{Z}}) = Z$ and $pi_M(M cap mathbb{Z}^n) = mathbb{Z}_{geq 0}$, the set of all nonnegative integers. The
linear map $pi_M$ induces an isomorphism from $L_{mathbb{Z}}/partial M_{mathbb{Z}}$ to $mathbb{Z}$.



I have the following question:



Q) Why the linear map $pi_M$ exists?



Thanks in advance.










share|cite|improve this question











$endgroup$




I am currently reading the paper "Newton-Okounkov bodies, semigroups of integral points, graded algebras and intersection theory" by Kiumars Kaveh, Askold Georgievich Khovanskii (paper). In the page 937 the following paragraph appears:



Let $L$ be a linear subspace in $mathbb{R}^n$ and $M$ a half-space in $L$ with boundary $partial M$. A half-space $M subset L$ is rational if the subspaces $L$ and $partial M$ can be spanned by integral vectors, i.e., are rational subspaces.



$hspace{5mm}$ With a rational half-space $M subset L$ one can associate $partial M_{mathbb{Z}} = partial M capmathbb{Z}^n$ and $L_{mathbb{Z}} = L cap mathbb{Z}^n$. Take the linear map $pi_M : L rightarrow mathbb{R}$ such that $ker(pi_M) = partial M$, $pi_M(L_{mathbb{Z}}) = Z$ and $pi_M(M cap mathbb{Z}^n) = mathbb{Z}_{geq 0}$, the set of all nonnegative integers. The
linear map $pi_M$ induces an isomorphism from $L_{mathbb{Z}}/partial M_{mathbb{Z}}$ to $mathbb{Z}$.



I have the following question:



Q) Why the linear map $pi_M$ exists?



Thanks in advance.







linear-algebra algebraic-geometry commutative-algebra convex-geometry






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share|cite|improve this question













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share|cite|improve this question








edited Dec 28 '18 at 9:21









KReiser

10.1k21435




10.1k21435










asked Dec 28 '18 at 8:53









tessellationtessellation

1,091613




1,091613












  • $begingroup$
    Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
    $endgroup$
    – KReiser
    Dec 28 '18 at 9:25


















  • $begingroup$
    Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
    $endgroup$
    – KReiser
    Dec 28 '18 at 9:25
















$begingroup$
Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
$endgroup$
– KReiser
Dec 28 '18 at 9:25




$begingroup$
Perhaps this is a bit eager, but why not just use the fact that as $partial M$ is a codimension-1 linear subspace in $L$, one may project onto the unique normal to $partial M$ inside $L$?
$endgroup$
– KReiser
Dec 28 '18 at 9:25










1 Answer
1






active

oldest

votes


















1












$begingroup$

$mathbb{Z}^n$ contains a vector normal to $partial M$ whose endpoint is in $M$ because $partial M$ is a rational subspace. Projection onto one of these normal vectors has all but one ($pi_M(L_{mathbb{Z}}) = mathbb{Z}$) of the listed properties because the integers form a ring.



Let $v in mathbb{Z}^n$, $v perp partial M$, $v in M$ and $pi_v$ be projection onto $v$. Then $pi_v(L_{mathbb{Z}}) = nmathbb{Z}$ for some $n in mathbb{Z}_{>0}$ (because the image is a torsion-free, rank $1$ $mathbb{Z}$-module). Take $pi_M = frac{1}{n} pi_v$.





Why does $mathbb{Z}^n$ contain a normal to $partial M$?




A constructive method labels the coordinates $x_1, dots , x_n$ then picks a permutation of these, $x_{sigma(1)}, dots, x_{sigma(n)}$. Then find the intersections of $partial M$ with the $x_{sigma(i)}x_{sigma(i+1)}$ coordinate planes, $i in [1,n-1]$. These intersections are lines with rational slopes. The perpendiculars to these intersections are also lines with rational slopes. Then, using the LCM, iteratively glue these vectors together to give a normal in $mathbb{Z}^n$.



For example, suppose the permutation is $x_1, x_3, x_2$, where I will use the friendlier labels $x, z, y$, respectively, and $partial M$'s intersections gives us coordinate plane perpendiculars through $(x,z) = (2,3)$ on the $xz$-plane and through $(y,z) = (7,2)$ on the $yz$-plane. The LCM of the $z$-components is $6$, so $2 cdot(2,3) = (4,6)$ and $3 cdot(7,2) = (21,6)$ assemble into $(4,21,6)$. If $n > 3$, we continue iterating through the permutation, having only one component of our current vector in common with the next coordinate plane perpendicular, so needing only one LCM to glue the new vector to the current vector.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
    $endgroup$
    – tessellation
    Dec 28 '18 at 12:57












  • $begingroup$
    @tessellation : Added.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:24










  • $begingroup$
    @MatthewTowers : Ah, right. Incommensurables... Fixing.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:58












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1 Answer
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active

oldest

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1 Answer
1






active

oldest

votes









active

oldest

votes






active

oldest

votes









1












$begingroup$

$mathbb{Z}^n$ contains a vector normal to $partial M$ whose endpoint is in $M$ because $partial M$ is a rational subspace. Projection onto one of these normal vectors has all but one ($pi_M(L_{mathbb{Z}}) = mathbb{Z}$) of the listed properties because the integers form a ring.



Let $v in mathbb{Z}^n$, $v perp partial M$, $v in M$ and $pi_v$ be projection onto $v$. Then $pi_v(L_{mathbb{Z}}) = nmathbb{Z}$ for some $n in mathbb{Z}_{>0}$ (because the image is a torsion-free, rank $1$ $mathbb{Z}$-module). Take $pi_M = frac{1}{n} pi_v$.





Why does $mathbb{Z}^n$ contain a normal to $partial M$?




A constructive method labels the coordinates $x_1, dots , x_n$ then picks a permutation of these, $x_{sigma(1)}, dots, x_{sigma(n)}$. Then find the intersections of $partial M$ with the $x_{sigma(i)}x_{sigma(i+1)}$ coordinate planes, $i in [1,n-1]$. These intersections are lines with rational slopes. The perpendiculars to these intersections are also lines with rational slopes. Then, using the LCM, iteratively glue these vectors together to give a normal in $mathbb{Z}^n$.



For example, suppose the permutation is $x_1, x_3, x_2$, where I will use the friendlier labels $x, z, y$, respectively, and $partial M$'s intersections gives us coordinate plane perpendiculars through $(x,z) = (2,3)$ on the $xz$-plane and through $(y,z) = (7,2)$ on the $yz$-plane. The LCM of the $z$-components is $6$, so $2 cdot(2,3) = (4,6)$ and $3 cdot(7,2) = (21,6)$ assemble into $(4,21,6)$. If $n > 3$, we continue iterating through the permutation, having only one component of our current vector in common with the next coordinate plane perpendicular, so needing only one LCM to glue the new vector to the current vector.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
    $endgroup$
    – tessellation
    Dec 28 '18 at 12:57












  • $begingroup$
    @tessellation : Added.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:24










  • $begingroup$
    @MatthewTowers : Ah, right. Incommensurables... Fixing.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:58
















1












$begingroup$

$mathbb{Z}^n$ contains a vector normal to $partial M$ whose endpoint is in $M$ because $partial M$ is a rational subspace. Projection onto one of these normal vectors has all but one ($pi_M(L_{mathbb{Z}}) = mathbb{Z}$) of the listed properties because the integers form a ring.



Let $v in mathbb{Z}^n$, $v perp partial M$, $v in M$ and $pi_v$ be projection onto $v$. Then $pi_v(L_{mathbb{Z}}) = nmathbb{Z}$ for some $n in mathbb{Z}_{>0}$ (because the image is a torsion-free, rank $1$ $mathbb{Z}$-module). Take $pi_M = frac{1}{n} pi_v$.





Why does $mathbb{Z}^n$ contain a normal to $partial M$?




A constructive method labels the coordinates $x_1, dots , x_n$ then picks a permutation of these, $x_{sigma(1)}, dots, x_{sigma(n)}$. Then find the intersections of $partial M$ with the $x_{sigma(i)}x_{sigma(i+1)}$ coordinate planes, $i in [1,n-1]$. These intersections are lines with rational slopes. The perpendiculars to these intersections are also lines with rational slopes. Then, using the LCM, iteratively glue these vectors together to give a normal in $mathbb{Z}^n$.



For example, suppose the permutation is $x_1, x_3, x_2$, where I will use the friendlier labels $x, z, y$, respectively, and $partial M$'s intersections gives us coordinate plane perpendiculars through $(x,z) = (2,3)$ on the $xz$-plane and through $(y,z) = (7,2)$ on the $yz$-plane. The LCM of the $z$-components is $6$, so $2 cdot(2,3) = (4,6)$ and $3 cdot(7,2) = (21,6)$ assemble into $(4,21,6)$. If $n > 3$, we continue iterating through the permutation, having only one component of our current vector in common with the next coordinate plane perpendicular, so needing only one LCM to glue the new vector to the current vector.






share|cite|improve this answer











$endgroup$













  • $begingroup$
    Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
    $endgroup$
    – tessellation
    Dec 28 '18 at 12:57












  • $begingroup$
    @tessellation : Added.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:24










  • $begingroup$
    @MatthewTowers : Ah, right. Incommensurables... Fixing.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:58














1












1








1





$begingroup$

$mathbb{Z}^n$ contains a vector normal to $partial M$ whose endpoint is in $M$ because $partial M$ is a rational subspace. Projection onto one of these normal vectors has all but one ($pi_M(L_{mathbb{Z}}) = mathbb{Z}$) of the listed properties because the integers form a ring.



Let $v in mathbb{Z}^n$, $v perp partial M$, $v in M$ and $pi_v$ be projection onto $v$. Then $pi_v(L_{mathbb{Z}}) = nmathbb{Z}$ for some $n in mathbb{Z}_{>0}$ (because the image is a torsion-free, rank $1$ $mathbb{Z}$-module). Take $pi_M = frac{1}{n} pi_v$.





Why does $mathbb{Z}^n$ contain a normal to $partial M$?




A constructive method labels the coordinates $x_1, dots , x_n$ then picks a permutation of these, $x_{sigma(1)}, dots, x_{sigma(n)}$. Then find the intersections of $partial M$ with the $x_{sigma(i)}x_{sigma(i+1)}$ coordinate planes, $i in [1,n-1]$. These intersections are lines with rational slopes. The perpendiculars to these intersections are also lines with rational slopes. Then, using the LCM, iteratively glue these vectors together to give a normal in $mathbb{Z}^n$.



For example, suppose the permutation is $x_1, x_3, x_2$, where I will use the friendlier labels $x, z, y$, respectively, and $partial M$'s intersections gives us coordinate plane perpendiculars through $(x,z) = (2,3)$ on the $xz$-plane and through $(y,z) = (7,2)$ on the $yz$-plane. The LCM of the $z$-components is $6$, so $2 cdot(2,3) = (4,6)$ and $3 cdot(7,2) = (21,6)$ assemble into $(4,21,6)$. If $n > 3$, we continue iterating through the permutation, having only one component of our current vector in common with the next coordinate plane perpendicular, so needing only one LCM to glue the new vector to the current vector.






share|cite|improve this answer











$endgroup$



$mathbb{Z}^n$ contains a vector normal to $partial M$ whose endpoint is in $M$ because $partial M$ is a rational subspace. Projection onto one of these normal vectors has all but one ($pi_M(L_{mathbb{Z}}) = mathbb{Z}$) of the listed properties because the integers form a ring.



Let $v in mathbb{Z}^n$, $v perp partial M$, $v in M$ and $pi_v$ be projection onto $v$. Then $pi_v(L_{mathbb{Z}}) = nmathbb{Z}$ for some $n in mathbb{Z}_{>0}$ (because the image is a torsion-free, rank $1$ $mathbb{Z}$-module). Take $pi_M = frac{1}{n} pi_v$.





Why does $mathbb{Z}^n$ contain a normal to $partial M$?




A constructive method labels the coordinates $x_1, dots , x_n$ then picks a permutation of these, $x_{sigma(1)}, dots, x_{sigma(n)}$. Then find the intersections of $partial M$ with the $x_{sigma(i)}x_{sigma(i+1)}$ coordinate planes, $i in [1,n-1]$. These intersections are lines with rational slopes. The perpendiculars to these intersections are also lines with rational slopes. Then, using the LCM, iteratively glue these vectors together to give a normal in $mathbb{Z}^n$.



For example, suppose the permutation is $x_1, x_3, x_2$, where I will use the friendlier labels $x, z, y$, respectively, and $partial M$'s intersections gives us coordinate plane perpendiculars through $(x,z) = (2,3)$ on the $xz$-plane and through $(y,z) = (7,2)$ on the $yz$-plane. The LCM of the $z$-components is $6$, so $2 cdot(2,3) = (4,6)$ and $3 cdot(7,2) = (21,6)$ assemble into $(4,21,6)$. If $n > 3$, we continue iterating through the permutation, having only one component of our current vector in common with the next coordinate plane perpendicular, so needing only one LCM to glue the new vector to the current vector.







share|cite|improve this answer














share|cite|improve this answer



share|cite|improve this answer








edited Dec 28 '18 at 17:29

























answered Dec 28 '18 at 9:25









Eric TowersEric Towers

33.9k22371




33.9k22371












  • $begingroup$
    Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
    $endgroup$
    – tessellation
    Dec 28 '18 at 12:57












  • $begingroup$
    @tessellation : Added.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:24










  • $begingroup$
    @MatthewTowers : Ah, right. Incommensurables... Fixing.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:58


















  • $begingroup$
    Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
    $endgroup$
    – tessellation
    Dec 28 '18 at 12:57












  • $begingroup$
    @tessellation : Added.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:24










  • $begingroup$
    @MatthewTowers : Ah, right. Incommensurables... Fixing.
    $endgroup$
    – Eric Towers
    Dec 28 '18 at 16:58
















$begingroup$
Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
$endgroup$
– tessellation
Dec 28 '18 at 12:57






$begingroup$
Could you please explain why a rational subspace must have a normal contained in $mathbb{Z}^n$.
$endgroup$
– tessellation
Dec 28 '18 at 12:57














$begingroup$
@tessellation : Added.
$endgroup$
– Eric Towers
Dec 28 '18 at 16:24




$begingroup$
@tessellation : Added.
$endgroup$
– Eric Towers
Dec 28 '18 at 16:24












$begingroup$
@MatthewTowers : Ah, right. Incommensurables... Fixing.
$endgroup$
– Eric Towers
Dec 28 '18 at 16:58




$begingroup$
@MatthewTowers : Ah, right. Incommensurables... Fixing.
$endgroup$
– Eric Towers
Dec 28 '18 at 16:58


















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