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Suppose that R is an integral domain. Any function N : R N {0} with N(0) = 0 is a norm. If N(a) > 0, a R \ {0 R }, then N is called a positive norm.

Suppose that R is an integral domain. Any function N : R N {0} with N(0) = 0 is a norm. If N(a) > 0, a R \ {0 R }, then N is called a positive norm. Definition An integral domain R is called a Euclidean Domain if R has a division algorithm. That is, if there is a norm N of R such that for any a, b R with b 0 R there exists q, r R satisfying: 1 a = bq + r, and 2 r = 0 R or N(r) < N(b). For such q, r R, q is called a quotient and r is called a remainder upon divison of a by b.

Note The existence of a division algorithm for a ring R allows employment of the Euclidean Algorithm in R for computation of greatest common divisors.

Note The existence of a division algorithm for a ring R allows employment of the Euclidean Algorithm in R for computation of greatest common divisors. If R is a Euclidean Domain, then every ideal is principal. More precisely, if I R, then I = (d) where d is any element of I of minimum norm.

Note The existence of a division algorithm for a ring R allows employment of the Euclidean Algorithm in R for computation of greatest common divisors. If R is a Euclidean Domain, then every ideal is principal. More precisely, if I R, then I = (d) where d is any element of I of minimum norm. Example Z is a Euclidean domain and thus all ideals of Z are principal. Q[x] is a Euclidean domain. Z[x] is not a Euclidean domain since one can check that (3, x) is not principal.

Let R be a commutative ring and let a, b R with b 0 R. 1 We say that a is a multiple of b if there is c R such that a = bc. We also say that b divides a and write b a. 2 A greatest common divisor of a and b (if it exists) is an element d R satisfying 1 d a and d b, and 2 if d R, d a and d b then d d also.

Let R be a commutative ring and let a, b R with b 0 R. 1 We say that a is a multiple of b if there is c R such that a = bc. We also say that b divides a and write b a. 2 A greatest common divisor of a and b (if it exists) is an element d R satisfying 1 d a and d b, and 2 if d R, d a and d b then d d also. If a, b R and (a, b) = (d) then d is a greatest common divisor of a and b.

Let R be a commutative ring and let a, b R with b 0 R. 1 We say that a is a multiple of b if there is c R such that a = bc. We also say that b divides a and write b a. 2 A greatest common divisor of a and b (if it exists) is an element d R satisfying 1 d a and d b, and 2 if d R, d a and d b then d d also. If a, b R and (a, b) = (d) then d is a greatest common divisor of a and b. Suppose that R is an integral domain and that d, d R. If (d) = (d ), then there is a unit u R such that d = ud. In particular, if d and d are greatest common divisors of a and b then d = ud for some u R.

Theorem Let R be a Euclidean domain and let a, b R be non-zero. Let d = r n be the final non-zero remainder in the Euclidean Algorithm. 1 d is a greatest common divisor of a and b, and 2 (a, b) = (d). In particular, d is an R-linear combination of a and b. That is there are x, y R such that d = ax + by.

Suppose that R is an integral domain. Denote by R = R {0 R }. We say that u R \ R is a universal side divisor if x R, z R such that u divides x z. That is, there is q R and z R such that x = qu + z.

Suppose that R is an integral domain. Denote by R = R {0 R }. We say that u R \ R is a universal side divisor if x R, z R such that u divides x z. That is, there is q R and z R such that x = qu + z. Let R be an integral domain that is not a field. If R is a Euclidean domain then R has universal side divisors.

Suppose that R is an integral domain. Denote by R = R {0 R }. We say that u R \ R is a universal side divisor if x R, z R such that u divides x z. That is, there is q R and z R such that x = qu + z. Let R be an integral domain that is not a field. If R is a Euclidean domain then R has universal side divisors. Example R = Z [ (1+ 19) 2 ] is an integral domain which has no universal side divisors and is therefore not a Euclidean domain.

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