12-240/Classnotes for Thursday September 13: Difference between revisions

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<math>\forall \!\,</math> a, b, c <math>\in \!\,</math> F, a.(b+c)=a.b + a.c
<math>\forall \!\,</math> a, b, c <math>\in \!\,</math> F, a.(b+c)=a.b + a.c


== Examples ==
== Significance ==


'''F5''' It makes sense to define an operation

-: F -> F called "negation"

For a <math>/in/;/,</math> F define -a to be equal that b in F for which a+b=0, i.e, a+(-a)=0


== Lecture Notes, upload by [[User:Starash|Starash]] ==
== Lecture Notes, upload by [[User:Starash|Starash]] ==

Revision as of 11:28, 14 September 2012

In the second day of the class, the professor continues on the definition of a field.

Definition of a field

Combined with a part from the first class, we have a complete definition as follow:

A field is a set "F' with two binary operations +,x defind on it, and two special elements 0 ≠ 1 such that

F1: commutative law

a, b F: a+b=b+a and a.b=b.a

F2: associative law

a, b, c F: (a+b)+c=a+(b+c) and (a.b).c= a.(b.c)


F3: the existence of identity elements

a F, a+o=a and a.1=a


F4: existence of inverses

a F , c, d F such that a+c=o and a.d=1


F5: contributive law

a, b, c F, a.(b+c)=a.b + a.c

Significance

F5 It makes sense to define an operation

-: F -> F called "negation"

For a F define -a to be equal that b in F for which a+b=0, i.e, a+(-a)=0

Lecture Notes, upload by Starash