Do there exist finite commutative rings with identity that are not Bézout rings?Example of finite ring which is not a Bézout ringWhen does a finite ring become a finite field?Does there exist an ordered ring, with $mathbbZ$ as an ordered subring, such that some ring of p-adic integers can be formed as a quotient ring?Characteristic collection of rings?Examples of Commutative Rings with $1$ that are not integral domains besides $mathbb Z/nmathbb Z$?Is there a theory of “rings” with partially defined multiplication?Characterize all finite unital rings with only zero divisorsThere are $10$ commutative rings of order $8$Enumerating finite local commutative rings effectivelyIs there an elementary way to prove that the algebraic integers are a Bézout domain?Does there exist a homomorphism of commutative rings with unit from $mathbbZ[x]/(x^2+3)$ to $mathbbZ[x]/(x^2-x+1)$
Is there any reason not to eat food that's been dropped on the surface of the moon?
How to be diplomatic in refusing to write code that breaches the privacy of our users
Your magic is very sketchy
Is this Spell Mimic feat balanced?
Increase performance creating Mandelbrot set in python
How does it work when somebody invests in my business?
Mapping a list into a phase plot
The plural of 'stomach"
How could Frankenstein get the parts for his _second_ creature?
Why does John Bercow say “unlock” after reading out the results of a vote?
Student evaluations of teaching assistants
Time travel short story where a man arrives in the late 19th century in a time machine and then sends the machine back into the past
What defines a dissertation?
What does this 7 mean above the f flat
If you attempt to grapple an opponent that you are hidden from, do they roll at disadvantage?
I'm in charge of equipment buying but no one's ever happy with what I choose. How to fix this?
Is a roofing delivery truck likely to crack my driveway slab?
Coordinate position not precise
Is there a problem with hiding "forgot password" until it's needed?
How will losing mobility of one hand affect my career as a programmer?
What is the opposite of 'gravitas'?
How do I define a right arrow with bar in LaTeX?
What's a natural way to say that someone works somewhere (for a job)?
What is difference between behavior and behaviour
Do there exist finite commutative rings with identity that are not Bézout rings?
Example of finite ring which is not a Bézout ringWhen does a finite ring become a finite field?Does there exist an ordered ring, with $mathbbZ$ as an ordered subring, such that some ring of p-adic integers can be formed as a quotient ring?Characteristic collection of rings?Examples of Commutative Rings with $1$ that are not integral domains besides $mathbb Z/nmathbb Z$?Is there a theory of “rings” with partially defined multiplication?Characterize all finite unital rings with only zero divisorsThere are $10$ commutative rings of order $8$Enumerating finite local commutative rings effectivelyIs there an elementary way to prove that the algebraic integers are a Bézout domain?Does there exist a homomorphism of commutative rings with unit from $mathbbZ[x]/(x^2+3)$ to $mathbbZ[x]/(x^2-x+1)$
$begingroup$
A similar question has been asked before: Example of finite ring which is not a Bézout ring, but has not been answered.
There also seems to be a dearth of resources online regarding this question. Some finite commutative rings that come to mind are $$mathbbZ/nmathbbZ, quadmathbbZ_2timesmathbbZ_2,$$ but all of them are Bézout rings. I was wondering if such rings are even possible, and what such an example of a ring might be.
To be clear, by Bézout ring, I mean a ring where Bézout's identity holds. Danke.
abstract-algebra ring-theory finite-fields finite-rings
edited 3 hours ago
Captain Lama
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
add a comment |
$begingroup$
A similar question has been asked before: Example of finite ring which is not a Bézout ring, but has not been answered.
There also seems to be a dearth of resources online regarding this question. Some finite commutative rings that come to mind are $$mathbbZ/nmathbbZ, quadmathbbZ_2timesmathbbZ_2,$$ but all of them are Bézout rings. I was wondering if such rings are even possible, and what such an example of a ring might be.
To be clear, by Bézout ring, I mean a ring where Bézout's identity holds. Danke.
abstract-algebra ring-theory finite-fields finite-rings
edited 3 hours ago
Captain Lama
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
2
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
1
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago
add a comment |
$begingroup$
A similar question has been asked before: Example of finite ring which is not a Bézout ring, but has not been answered.
There also seems to be a dearth of resources online regarding this question. Some finite commutative rings that come to mind are $$mathbbZ/nmathbbZ, quadmathbbZ_2timesmathbbZ_2,$$ but all of them are Bézout rings. I was wondering if such rings are even possible, and what such an example of a ring might be.
To be clear, by Bézout ring, I mean a ring where Bézout's identity holds. Danke.
abstract-algebra ring-theory finite-fields finite-rings
edited 3 hours ago
Captain Lama
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
A similar question has been asked before: Example of finite ring which is not a Bézout ring, but has not been answered.
There also seems to be a dearth of resources online regarding this question. Some finite commutative rings that come to mind are $$mathbbZ/nmathbbZ, quadmathbbZ_2timesmathbbZ_2,$$ but all of them are Bézout rings. I was wondering if such rings are even possible, and what such an example of a ring might be.
To be clear, by Bézout ring, I mean a ring where Bézout's identity holds. Danke.
abstract-algebra ring-theory finite-fields finite-rings
abstract-algebra ring-theory finite-fields finite-rings
edited 3 hours ago
Captain Lama
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited 3 hours ago
Captain Lama
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited 3 hours ago
Captain Lama
10.1k1030
edited 3 hours ago
Captain Lama
10.1k1030
edited 3 hours ago
Captain Lama
10.1k1030
10.1k1030
asked 4 hours ago
magikarrrpmagikarrrp
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
asked 4 hours ago
magikarrrpmagikarrrp
112
asked 4 hours ago
magikarrrpmagikarrrp
112
112
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
New contributor
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
magikarrrp is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
2
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
1
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago
add a comment |
2
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
1
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago
2
2
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
1
1
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago
add a comment |
2 Answers
2
active
oldest
votes
$begingroup$
I will work with the definition of Bézout ring provided by Bernard in the comments. Since every ideal of a finite ring is manifestly finitely generated, this amounts to asking whether there are finite rings which are not principal ideal rings (i.e., rings in which every ideal is principal).
Indeed, there are many examples of such rings. Here is one construction: let $F$ be any finite field you like, let $R = F[X, Y], mathfrakm = langle X, Yrangle$, and put $A = R/mathfrakm^2$. Then $A$ is a finite ring; indeed, it is an $F$-vector space of dimension $3$, with basis $overline1, overlineX, overlineY$, and so has $|F|^3$ elements. However, the ideal $I := mathfrakm/mathfrakm^2$ of $A$ is not principal. There are a number of ways to see this, but the point is that $I$ is $I$-torsion as an $A$-module, so the $A$-module structure on $I$ coincides with the induced $A/I cong R/mathfrakm cong F$-module structure on $I$. Clearly, $I$ is free of rank two as an $F$-module on the classes $overlineX, overlineY$, so $I$ requires two generators as an $A$-module.
Incidentally, $A$ is also a local ring with unique maximal ideal $I$, so this gives an answer to one of the questions in the (unanswered) linked question in your post.
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
$endgroup$
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
add a comment |
$begingroup$
Based on your comment to Bernard, I'm fairly sure that this answer will not be helpful to you, since you say that you aren't yet familiar with ideals. However, I have no idea how to approach this question without such notions.
I'm assuming your definition of Bezout ring is the same as that given by Bernard in the comments, that a ring $R$ is a Bezout ring if its finitely generated ideals are principal. Since $R$ is finite, $R$ is a Bezout ring if and only if all of its ideals are principal (since every ideal is finite, and thus finitely generated).
The answer is no.
Let $k$ be a finite field. $V$ a finite dimensional vector space over the field.
Define $R=koplus V$ to be the ring with multiplication $(c,v)cdot (d,w)=(cd,cw+dv)$.
The proper ideals of $R$ are the vector subspaces of $V$, and the proper ideals generated by a single element are the zero and one-dimensional subspaces of $V$. Thus if $V$ is two dimensional, the ideal $V$ is not principal.
Attempting to translate this into more elementary language:
Let $BbbF_p=BbbZ/pBbbZ$ for some prime $p$.
Define $R=BbbF_p^3$, with pointwise addition and multiplication given by $(a,b,c)(d,e,f) = (ad,ae+db,af+dc)$. Then the ideal $(0,*,*)$ (I'm using $*$ to denote allowing that element of the tuple to be anything in the field) is not principal, since the ideal generated by a single element $(a,b,c)$ is either $(0,0,0)$ if $a=b=c=0$, or $R$ if $ane 0$ (since $$(a^-1,-a^-2b,-a^-2c)(a,b,c)=(1,0,0),$$ which is the unit of $R$), or
$$ (0,tb,tc) : tinBbbF_p ,$$
when $a=0$, since
$$(0,b,c)(t,x,y)=(0,tb,tc).$$
This means that the elements $e_1=(0,1,0)$ and $e_2=(0,0,1)$ do not satisfy a Bezout type identity, (though to be honest, it's not entirely what that identity should be when we are not working in a domain).
answered 1 hour ago
jgonjgon
15.8k32143
$endgroup$
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
add a comment |
Your Answer
StackExchange.ifUsing("editor", function ()
return StackExchange.using("mathjaxEditing", function ()
StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix)
StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
);
);
, "mathjax-editing");
StackExchange.ready(function()
var channelOptions =
tags: "".split(" "),
id: "69"
;
initTagRenderer("".split(" "), "".split(" "), channelOptions);
StackExchange.using("externalEditor", function()
// Have to fire editor after snippets, if snippets enabled
if (StackExchange.settings.snippets.snippetsEnabled)
StackExchange.using("snippets", function()
createEditor();
);
else
createEditor();
);
function createEditor()
StackExchange.prepareEditor(
heartbeatType: 'answer',
autoActivateHeartbeat: false,
convertImagesToLinks: true,
noModals: true,
showLowRepImageUploadWarning: true,
reputationToPostImages: 10,
bindNavPrevention: true,
postfix: "",
imageUploader:
brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
allowUrls: true
,
noCode: true, onDemand: true,
discardSelector: ".discard-answer"
,immediatelyShowMarkdownHelp:true
);
);
magikarrrp is a new contributor. Be nice, and check out our Code of Conduct.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
var $window = $(window),
onScroll = function(e)
var $elem = $('.new-login-left'),
docViewTop = $window.scrollTop(),
docViewBottom = docViewTop + $window.height(),
elemTop = $elem.offset().top,
elemBottom = elemTop + $elem.height();
if ((docViewTop elemBottom))
StackExchange.using('gps', function() StackExchange.gps.track('embedded_signup_form.view', location: 'question_page' ); );
$window.unbind('scroll', onScroll);
;
$window.on('scroll', onScroll);
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3163889%2fdo-there-exist-finite-commutative-rings-with-identity-that-are-not-b%25c3%25a9zout-rings%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
I will work with the definition of Bézout ring provided by Bernard in the comments. Since every ideal of a finite ring is manifestly finitely generated, this amounts to asking whether there are finite rings which are not principal ideal rings (i.e., rings in which every ideal is principal).
Indeed, there are many examples of such rings. Here is one construction: let $F$ be any finite field you like, let $R = F[X, Y], mathfrakm = langle X, Yrangle$, and put $A = R/mathfrakm^2$. Then $A$ is a finite ring; indeed, it is an $F$-vector space of dimension $3$, with basis $overline1, overlineX, overlineY$, and so has $|F|^3$ elements. However, the ideal $I := mathfrakm/mathfrakm^2$ of $A$ is not principal. There are a number of ways to see this, but the point is that $I$ is $I$-torsion as an $A$-module, so the $A$-module structure on $I$ coincides with the induced $A/I cong R/mathfrakm cong F$-module structure on $I$. Clearly, $I$ is free of rank two as an $F$-module on the classes $overlineX, overlineY$, so $I$ requires two generators as an $A$-module.
Incidentally, $A$ is also a local ring with unique maximal ideal $I$, so this gives an answer to one of the questions in the (unanswered) linked question in your post.
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
$endgroup$
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
add a comment |
$begingroup$
I will work with the definition of Bézout ring provided by Bernard in the comments. Since every ideal of a finite ring is manifestly finitely generated, this amounts to asking whether there are finite rings which are not principal ideal rings (i.e., rings in which every ideal is principal).
Indeed, there are many examples of such rings. Here is one construction: let $F$ be any finite field you like, let $R = F[X, Y], mathfrakm = langle X, Yrangle$, and put $A = R/mathfrakm^2$. Then $A$ is a finite ring; indeed, it is an $F$-vector space of dimension $3$, with basis $overline1, overlineX, overlineY$, and so has $|F|^3$ elements. However, the ideal $I := mathfrakm/mathfrakm^2$ of $A$ is not principal. There are a number of ways to see this, but the point is that $I$ is $I$-torsion as an $A$-module, so the $A$-module structure on $I$ coincides with the induced $A/I cong R/mathfrakm cong F$-module structure on $I$. Clearly, $I$ is free of rank two as an $F$-module on the classes $overlineX, overlineY$, so $I$ requires two generators as an $A$-module.
Incidentally, $A$ is also a local ring with unique maximal ideal $I$, so this gives an answer to one of the questions in the (unanswered) linked question in your post.
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
$endgroup$
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
add a comment |
$begingroup$
I will work with the definition of Bézout ring provided by Bernard in the comments. Since every ideal of a finite ring is manifestly finitely generated, this amounts to asking whether there are finite rings which are not principal ideal rings (i.e., rings in which every ideal is principal).
Indeed, there are many examples of such rings. Here is one construction: let $F$ be any finite field you like, let $R = F[X, Y], mathfrakm = langle X, Yrangle$, and put $A = R/mathfrakm^2$. Then $A$ is a finite ring; indeed, it is an $F$-vector space of dimension $3$, with basis $overline1, overlineX, overlineY$, and so has $|F|^3$ elements. However, the ideal $I := mathfrakm/mathfrakm^2$ of $A$ is not principal. There are a number of ways to see this, but the point is that $I$ is $I$-torsion as an $A$-module, so the $A$-module structure on $I$ coincides with the induced $A/I cong R/mathfrakm cong F$-module structure on $I$. Clearly, $I$ is free of rank two as an $F$-module on the classes $overlineX, overlineY$, so $I$ requires two generators as an $A$-module.
Incidentally, $A$ is also a local ring with unique maximal ideal $I$, so this gives an answer to one of the questions in the (unanswered) linked question in your post.
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
$endgroup$
I will work with the definition of Bézout ring provided by Bernard in the comments. Since every ideal of a finite ring is manifestly finitely generated, this amounts to asking whether there are finite rings which are not principal ideal rings (i.e., rings in which every ideal is principal).
Indeed, there are many examples of such rings. Here is one construction: let $F$ be any finite field you like, let $R = F[X, Y], mathfrakm = langle X, Yrangle$, and put $A = R/mathfrakm^2$. Then $A$ is a finite ring; indeed, it is an $F$-vector space of dimension $3$, with basis $overline1, overlineX, overlineY$, and so has $|F|^3$ elements. However, the ideal $I := mathfrakm/mathfrakm^2$ of $A$ is not principal. There are a number of ways to see this, but the point is that $I$ is $I$-torsion as an $A$-module, so the $A$-module structure on $I$ coincides with the induced $A/I cong R/mathfrakm cong F$-module structure on $I$. Clearly, $I$ is free of rank two as an $F$-module on the classes $overlineX, overlineY$, so $I$ requires two generators as an $A$-module.
Incidentally, $A$ is also a local ring with unique maximal ideal $I$, so this gives an answer to one of the questions in the (unanswered) linked question in your post.
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
edited 4 hours ago
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
answered 4 hours ago
Alex WertheimAlex Wertheim
16.1k22848
16.1k22848
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
add a comment |
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
2
2
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
Since the OP states they are not familiar with ideals, maybe it is useful to give a more ad hoc description of $A$: you can see $A$ as $F^3$ as an additive group, with the product $(x,y,z)cdot (x',y',z') = (xx',xy'+x'y,xz'+x'z)$.
$endgroup$
– Captain Lama
3 hours ago
add a comment |
$begingroup$
Based on your comment to Bernard, I'm fairly sure that this answer will not be helpful to you, since you say that you aren't yet familiar with ideals. However, I have no idea how to approach this question without such notions.
I'm assuming your definition of Bezout ring is the same as that given by Bernard in the comments, that a ring $R$ is a Bezout ring if its finitely generated ideals are principal. Since $R$ is finite, $R$ is a Bezout ring if and only if all of its ideals are principal (since every ideal is finite, and thus finitely generated).
The answer is no.
Let $k$ be a finite field. $V$ a finite dimensional vector space over the field.
Define $R=koplus V$ to be the ring with multiplication $(c,v)cdot (d,w)=(cd,cw+dv)$.
The proper ideals of $R$ are the vector subspaces of $V$, and the proper ideals generated by a single element are the zero and one-dimensional subspaces of $V$. Thus if $V$ is two dimensional, the ideal $V$ is not principal.
Attempting to translate this into more elementary language:
Let $BbbF_p=BbbZ/pBbbZ$ for some prime $p$.
Define $R=BbbF_p^3$, with pointwise addition and multiplication given by $(a,b,c)(d,e,f) = (ad,ae+db,af+dc)$. Then the ideal $(0,*,*)$ (I'm using $*$ to denote allowing that element of the tuple to be anything in the field) is not principal, since the ideal generated by a single element $(a,b,c)$ is either $(0,0,0)$ if $a=b=c=0$, or $R$ if $ane 0$ (since $$(a^-1,-a^-2b,-a^-2c)(a,b,c)=(1,0,0),$$ which is the unit of $R$), or
$$ (0,tb,tc) : tinBbbF_p ,$$
when $a=0$, since
$$(0,b,c)(t,x,y)=(0,tb,tc).$$
This means that the elements $e_1=(0,1,0)$ and $e_2=(0,0,1)$ do not satisfy a Bezout type identity, (though to be honest, it's not entirely what that identity should be when we are not working in a domain).
answered 1 hour ago
jgonjgon
15.8k32143
$endgroup$
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
add a comment |
$begingroup$
Based on your comment to Bernard, I'm fairly sure that this answer will not be helpful to you, since you say that you aren't yet familiar with ideals. However, I have no idea how to approach this question without such notions.
I'm assuming your definition of Bezout ring is the same as that given by Bernard in the comments, that a ring $R$ is a Bezout ring if its finitely generated ideals are principal. Since $R$ is finite, $R$ is a Bezout ring if and only if all of its ideals are principal (since every ideal is finite, and thus finitely generated).
The answer is no.
Let $k$ be a finite field. $V$ a finite dimensional vector space over the field.
Define $R=koplus V$ to be the ring with multiplication $(c,v)cdot (d,w)=(cd,cw+dv)$.
The proper ideals of $R$ are the vector subspaces of $V$, and the proper ideals generated by a single element are the zero and one-dimensional subspaces of $V$. Thus if $V$ is two dimensional, the ideal $V$ is not principal.
Attempting to translate this into more elementary language:
Let $BbbF_p=BbbZ/pBbbZ$ for some prime $p$.
Define $R=BbbF_p^3$, with pointwise addition and multiplication given by $(a,b,c)(d,e,f) = (ad,ae+db,af+dc)$. Then the ideal $(0,*,*)$ (I'm using $*$ to denote allowing that element of the tuple to be anything in the field) is not principal, since the ideal generated by a single element $(a,b,c)$ is either $(0,0,0)$ if $a=b=c=0$, or $R$ if $ane 0$ (since $$(a^-1,-a^-2b,-a^-2c)(a,b,c)=(1,0,0),$$ which is the unit of $R$), or
$$ (0,tb,tc) : tinBbbF_p ,$$
when $a=0$, since
$$(0,b,c)(t,x,y)=(0,tb,tc).$$
This means that the elements $e_1=(0,1,0)$ and $e_2=(0,0,1)$ do not satisfy a Bezout type identity, (though to be honest, it's not entirely what that identity should be when we are not working in a domain).
answered 1 hour ago
jgonjgon
15.8k32143
$endgroup$
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
add a comment |
$begingroup$
Based on your comment to Bernard, I'm fairly sure that this answer will not be helpful to you, since you say that you aren't yet familiar with ideals. However, I have no idea how to approach this question without such notions.
I'm assuming your definition of Bezout ring is the same as that given by Bernard in the comments, that a ring $R$ is a Bezout ring if its finitely generated ideals are principal. Since $R$ is finite, $R$ is a Bezout ring if and only if all of its ideals are principal (since every ideal is finite, and thus finitely generated).
The answer is no.
Let $k$ be a finite field. $V$ a finite dimensional vector space over the field.
Define $R=koplus V$ to be the ring with multiplication $(c,v)cdot (d,w)=(cd,cw+dv)$.
The proper ideals of $R$ are the vector subspaces of $V$, and the proper ideals generated by a single element are the zero and one-dimensional subspaces of $V$. Thus if $V$ is two dimensional, the ideal $V$ is not principal.
Attempting to translate this into more elementary language:
Let $BbbF_p=BbbZ/pBbbZ$ for some prime $p$.
Define $R=BbbF_p^3$, with pointwise addition and multiplication given by $(a,b,c)(d,e,f) = (ad,ae+db,af+dc)$. Then the ideal $(0,*,*)$ (I'm using $*$ to denote allowing that element of the tuple to be anything in the field) is not principal, since the ideal generated by a single element $(a,b,c)$ is either $(0,0,0)$ if $a=b=c=0$, or $R$ if $ane 0$ (since $$(a^-1,-a^-2b,-a^-2c)(a,b,c)=(1,0,0),$$ which is the unit of $R$), or
$$ (0,tb,tc) : tinBbbF_p ,$$
when $a=0$, since
$$(0,b,c)(t,x,y)=(0,tb,tc).$$
This means that the elements $e_1=(0,1,0)$ and $e_2=(0,0,1)$ do not satisfy a Bezout type identity, (though to be honest, it's not entirely what that identity should be when we are not working in a domain).
answered 1 hour ago
jgonjgon
15.8k32143
$endgroup$
Based on your comment to Bernard, I'm fairly sure that this answer will not be helpful to you, since you say that you aren't yet familiar with ideals. However, I have no idea how to approach this question without such notions.
I'm assuming your definition of Bezout ring is the same as that given by Bernard in the comments, that a ring $R$ is a Bezout ring if its finitely generated ideals are principal. Since $R$ is finite, $R$ is a Bezout ring if and only if all of its ideals are principal (since every ideal is finite, and thus finitely generated).
The answer is no.
Let $k$ be a finite field. $V$ a finite dimensional vector space over the field.
Define $R=koplus V$ to be the ring with multiplication $(c,v)cdot (d,w)=(cd,cw+dv)$.
The proper ideals of $R$ are the vector subspaces of $V$, and the proper ideals generated by a single element are the zero and one-dimensional subspaces of $V$. Thus if $V$ is two dimensional, the ideal $V$ is not principal.
Attempting to translate this into more elementary language:
Let $BbbF_p=BbbZ/pBbbZ$ for some prime $p$.
Define $R=BbbF_p^3$, with pointwise addition and multiplication given by $(a,b,c)(d,e,f) = (ad,ae+db,af+dc)$. Then the ideal $(0,*,*)$ (I'm using $*$ to denote allowing that element of the tuple to be anything in the field) is not principal, since the ideal generated by a single element $(a,b,c)$ is either $(0,0,0)$ if $a=b=c=0$, or $R$ if $ane 0$ (since $$(a^-1,-a^-2b,-a^-2c)(a,b,c)=(1,0,0),$$ which is the unit of $R$), or
$$ (0,tb,tc) : tinBbbF_p ,$$
when $a=0$, since
$$(0,b,c)(t,x,y)=(0,tb,tc).$$
This means that the elements $e_1=(0,1,0)$ and $e_2=(0,0,1)$ do not satisfy a Bezout type identity, (though to be honest, it's not entirely what that identity should be when we are not working in a domain).
answered 1 hour ago
jgonjgon
15.8k32143
answered 1 hour ago
jgonjgon
15.8k32143
answered 1 hour ago
jgonjgon
15.8k32143
answered 1 hour ago
jgonjgon
15.8k32143
15.8k32143
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
add a comment |
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
I had to go do work after composing most of this, and after posting, I see that there is another answer with a similar strategy. Oh well.
$endgroup$
– jgon
1 hour ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
$begingroup$
Nice answer! I don't really see any problem with the similarity between our two answers, since yours is (as you say) translated into more elementary language that might appeal to the OP. (I elected not to, since, as you point out, I'm not sure what a Bezout identity should be in non-domains.)
$endgroup$
– Alex Wertheim
42 mins ago
add a comment |
magikarrrp is a new contributor. Be nice, and check out our Code of Conduct.
magikarrrp is a new contributor. Be nice, and check out our Code of Conduct.
magikarrrp is a new contributor. Be nice, and check out our Code of Conduct.
magikarrrp is a new contributor. Be nice, and check out our Code of Conduct.
Thanks for contributing an answer to Mathematics Stack Exchange!
- Please be sure to answer the question. Provide details and share your research!
But avoid …
- Asking for help, clarification, or responding to other answers.
- Making statements based on opinion; back them up with references or personal experience.
Use MathJax to format equations. MathJax reference.
To learn more, see our tips on writing great answers.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
var $window = $(window),
onScroll = function(e)
var $elem = $('.new-login-left'),
docViewTop = $window.scrollTop(),
docViewBottom = docViewTop + $window.height(),
elemTop = $elem.offset().top,
elemBottom = elemTop + $elem.height();
if ((docViewTop elemBottom))
StackExchange.using('gps', function() StackExchange.gps.track('embedded_signup_form.view', location: 'question_page' ); );
$window.unbind('scroll', onScroll);
;
$window.on('scroll', onScroll);
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3163889%2fdo-there-exist-finite-commutative-rings-with-identity-that-are-not-b%25c3%25a9zout-rings%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
var $window = $(window),
onScroll = function(e)
var $elem = $('.new-login-left'),
docViewTop = $window.scrollTop(),
docViewBottom = docViewTop + $window.height(),
elemTop = $elem.offset().top,
elemBottom = elemTop + $elem.height();
if ((docViewTop elemBottom))
StackExchange.using('gps', function() StackExchange.gps.track('embedded_signup_form.view', location: 'question_page' ); );
$window.unbind('scroll', onScroll);
;
$window.on('scroll', onScroll);
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
var $window = $(window),
onScroll = function(e)
var $elem = $('.new-login-left'),
docViewTop = $window.scrollTop(),
docViewBottom = docViewTop + $window.height(),
elemTop = $elem.offset().top,
elemBottom = elemTop + $elem.height();
if ((docViewTop elemBottom))
StackExchange.using('gps', function() StackExchange.gps.track('embedded_signup_form.view', location: 'question_page' ); );
$window.unbind('scroll', onScroll);
;
$window.on('scroll', onScroll);
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
var $window = $(window),
onScroll = function(e)
var $elem = $('.new-login-left'),
docViewTop = $window.scrollTop(),
docViewBottom = docViewTop + $window.height(),
elemTop = $elem.offset().top,
elemBottom = elemTop + $elem.height();
if ((docViewTop elemBottom))
StackExchange.using('gps', function() StackExchange.gps.track('embedded_signup_form.view', location: 'question_page' ); );
$window.unbind('scroll', onScroll);
;
$window.on('scroll', onScroll);
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
Required, but never shown
2
$begingroup$
For Bourbaki, a Bézout ring is a unital ring in which finitely generated ideals are principal. Is it equivalent to your definition?
$endgroup$
– Bernard
4 hours ago
$begingroup$
I haven't covered ideals yet in my studies, so I am honestly not sure.
$endgroup$
– magikarrrp
4 hours ago
1
$begingroup$
Be careful, the ring $M_n(mathbbF_q)$ is not commutative if $n$ is at least 2.
$endgroup$
– Captain Lama
3 hours ago
$begingroup$
@CaptainLama: good point! I have updated the description
$endgroup$
– magikarrrp
3 hours ago