Can anyone make me understand in simple language why the second condition for being an Euclidean domain is...
Can anyone make me understand in simple language why the second condition for being an Euclidean domain is superfluous ?
Why $v(a) leq v(ab)$ is not needed? How we can deduce from the first one?
abstract-algebra ring-theory integral-domain euclidean-domain
asked Dec 7 at 14:44
cmi
1,000212
add a comment |
Can anyone make me understand in simple language why the second condition for being an Euclidean domain is superfluous ?
Why $v(a) leq v(ab)$ is not needed? How we can deduce from the first one?
abstract-algebra ring-theory integral-domain euclidean-domain
asked Dec 7 at 14:44
cmi
1,000212
Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
1
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
1
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20
add a comment |
Can anyone make me understand in simple language why the second condition for being an Euclidean domain is superfluous ?
Why $v(a) leq v(ab)$ is not needed? How we can deduce from the first one?
abstract-algebra ring-theory integral-domain euclidean-domain
asked Dec 7 at 14:44
cmi
1,000212
Can anyone make me understand in simple language why the second condition for being an Euclidean domain is superfluous ?
Why $v(a) leq v(ab)$ is not needed? How we can deduce from the first one?
abstract-algebra ring-theory integral-domain euclidean-domain
abstract-algebra ring-theory integral-domain euclidean-domain
asked Dec 7 at 14:44
cmi
1,000212
asked Dec 7 at 14:44
cmi
1,000212
asked Dec 7 at 14:44
cmi
1,000212
asked Dec 7 at 14:44
cmi
1,000212
asked Dec 7 at 14:44
cmi
1,000212
1,000212
Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
1
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
1
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20
add a comment |
Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
1
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
1
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20
Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
1
1
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
1
1
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20
add a comment |
1 Answer
1
active
oldest
votes
Suppose $V$ only satisfies the first Euclidean property, i.e. for all $,a,bin D,$ if $,bneq 0,$ then there are $,q,rin D,$ such that $, a = qb +r,$ with $, V(r) < V(b),,$ where $V$ maps $D$ into (well-ordered) $,Bbb N$.
Derive $,v,$ from $,V,$ as follows
$$begin{align}
v(0) &= V(0)\
v(a) &= {rm min}{ V(b) : bin aDbackslash 0}
end{align}$$
Note $,v(a)le V(a),$ since it is clear if $,a = 0,,$ else it it follows by $, ain aDbackslash 0$
$v$ is also a Euclidean function: if $,a,bin D,$ and $,bneq 0,$ then $,v(b) = V(bc),$ for $,0neq cin D.,$ Since $,V,$ is a Euclidean function there exist $,q,rin D,$ such that $, a = qbc + r,$ and $,V(r) < V(bc) = v(b).,$ But by above we know $,v(r)le V(r),$ thus $,v(r) < v(b),,$ so $,v,$ is a Euclidean function.
Note $, v(a) le v(ab),$ if $,abneq 0,$ since $,aDbackslash 0supseteq abDbackslash 0$ $,Rightarrow,{rm min},V(aDbackslash 0) le {rm min}, V(abDbackslash 0)$
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
add a comment |
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Suppose $V$ only satisfies the first Euclidean property, i.e. for all $,a,bin D,$ if $,bneq 0,$ then there are $,q,rin D,$ such that $, a = qb +r,$ with $, V(r) < V(b),,$ where $V$ maps $D$ into (well-ordered) $,Bbb N$.
Derive $,v,$ from $,V,$ as follows
$$begin{align}
v(0) &= V(0)\
v(a) &= {rm min}{ V(b) : bin aDbackslash 0}
end{align}$$
Note $,v(a)le V(a),$ since it is clear if $,a = 0,,$ else it it follows by $, ain aDbackslash 0$
$v$ is also a Euclidean function: if $,a,bin D,$ and $,bneq 0,$ then $,v(b) = V(bc),$ for $,0neq cin D.,$ Since $,V,$ is a Euclidean function there exist $,q,rin D,$ such that $, a = qbc + r,$ and $,V(r) < V(bc) = v(b).,$ But by above we know $,v(r)le V(r),$ thus $,v(r) < v(b),,$ so $,v,$ is a Euclidean function.
Note $, v(a) le v(ab),$ if $,abneq 0,$ since $,aDbackslash 0supseteq abDbackslash 0$ $,Rightarrow,{rm min},V(aDbackslash 0) le {rm min}, V(abDbackslash 0)$
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
add a comment |
Suppose $V$ only satisfies the first Euclidean property, i.e. for all $,a,bin D,$ if $,bneq 0,$ then there are $,q,rin D,$ such that $, a = qb +r,$ with $, V(r) < V(b),,$ where $V$ maps $D$ into (well-ordered) $,Bbb N$.
Derive $,v,$ from $,V,$ as follows
$$begin{align}
v(0) &= V(0)\
v(a) &= {rm min}{ V(b) : bin aDbackslash 0}
end{align}$$
Note $,v(a)le V(a),$ since it is clear if $,a = 0,,$ else it it follows by $, ain aDbackslash 0$
$v$ is also a Euclidean function: if $,a,bin D,$ and $,bneq 0,$ then $,v(b) = V(bc),$ for $,0neq cin D.,$ Since $,V,$ is a Euclidean function there exist $,q,rin D,$ such that $, a = qbc + r,$ and $,V(r) < V(bc) = v(b).,$ But by above we know $,v(r)le V(r),$ thus $,v(r) < v(b),,$ so $,v,$ is a Euclidean function.
Note $, v(a) le v(ab),$ if $,abneq 0,$ since $,aDbackslash 0supseteq abDbackslash 0$ $,Rightarrow,{rm min},V(aDbackslash 0) le {rm min}, V(abDbackslash 0)$
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
add a comment |
Suppose $V$ only satisfies the first Euclidean property, i.e. for all $,a,bin D,$ if $,bneq 0,$ then there are $,q,rin D,$ such that $, a = qb +r,$ with $, V(r) < V(b),,$ where $V$ maps $D$ into (well-ordered) $,Bbb N$.
Derive $,v,$ from $,V,$ as follows
$$begin{align}
v(0) &= V(0)\
v(a) &= {rm min}{ V(b) : bin aDbackslash 0}
end{align}$$
Note $,v(a)le V(a),$ since it is clear if $,a = 0,,$ else it it follows by $, ain aDbackslash 0$
$v$ is also a Euclidean function: if $,a,bin D,$ and $,bneq 0,$ then $,v(b) = V(bc),$ for $,0neq cin D.,$ Since $,V,$ is a Euclidean function there exist $,q,rin D,$ such that $, a = qbc + r,$ and $,V(r) < V(bc) = v(b).,$ But by above we know $,v(r)le V(r),$ thus $,v(r) < v(b),,$ so $,v,$ is a Euclidean function.
Note $, v(a) le v(ab),$ if $,abneq 0,$ since $,aDbackslash 0supseteq abDbackslash 0$ $,Rightarrow,{rm min},V(aDbackslash 0) le {rm min}, V(abDbackslash 0)$
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
Suppose $V$ only satisfies the first Euclidean property, i.e. for all $,a,bin D,$ if $,bneq 0,$ then there are $,q,rin D,$ such that $, a = qb +r,$ with $, V(r) < V(b),,$ where $V$ maps $D$ into (well-ordered) $,Bbb N$.
Derive $,v,$ from $,V,$ as follows
$$begin{align}
v(0) &= V(0)\
v(a) &= {rm min}{ V(b) : bin aDbackslash 0}
end{align}$$
Note $,v(a)le V(a),$ since it is clear if $,a = 0,,$ else it it follows by $, ain aDbackslash 0$
$v$ is also a Euclidean function: if $,a,bin D,$ and $,bneq 0,$ then $,v(b) = V(bc),$ for $,0neq cin D.,$ Since $,V,$ is a Euclidean function there exist $,q,rin D,$ such that $, a = qbc + r,$ and $,V(r) < V(bc) = v(b).,$ But by above we know $,v(r)le V(r),$ thus $,v(r) < v(b),,$ so $,v,$ is a Euclidean function.
Note $, v(a) le v(ab),$ if $,abneq 0,$ since $,aDbackslash 0supseteq abDbackslash 0$ $,Rightarrow,{rm min},V(aDbackslash 0) le {rm min}, V(abDbackslash 0)$
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
edited Dec 7 at 17:14
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
answered Dec 7 at 16:46
Bill Dubuque
208k29190626
208k29190626
add a comment |
add a comment |
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Euclidean domain.
– MisterRiemann
Dec 7 at 14:48
1
It would be good if you could elaborate exactly which part of the construction you find to be "not comprehensible".
– MisterRiemann
Dec 7 at 15:12
How the new function satisfies the division algorithm?@MisterRiemann
– cmi
Dec 7 at 15:13
1
I'm not really an algebraist, so I'm learning this as we speak. Here is another reference, which seems to a bit more in-depth about this. (In particular, see Theorem 2.1).
– MisterRiemann
Dec 7 at 15:20