Jump to content

PlanetPhysics/R Module

From Wikiversity

\newcommand{\sqdiagram}[9]{Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikiversity.org/v1/":): {\displaystyle \diagram #1 \rto^{#2} \dto_{#4}& \eqno{\mbox{#9}}} }

R-Module and left/right module definitions

[edit | edit source]

Consider a ring with identity. Then a left module over is defined as a set with two binary operations, and such that

  1. Failed to parse (unknown function "\u"): {\displaystyle (\u+\v)+\w = \u+(\v+\w)} for all Failed to parse (unknown function "\u"): {\displaystyle \u,\v,\w \in M_L}
  2. Failed to parse (unknown function "\u"): {\displaystyle \u+\v=\v+\u} for all Failed to parse (unknown function "\u"): {\displaystyle \u,\v\in M_L}
  3. There exists an element Failed to parse (syntax error): {\displaystyle \0 \in M_L} such that Failed to parse (unknown function "\u"): {\displaystyle \u+\0=\u} for all Failed to parse (unknown function "\u"): {\displaystyle \u \in M_L}
  4. For any Failed to parse (unknown function "\u"): {\displaystyle \u \in M_L} , there exists an element Failed to parse (unknown function "\v"): {\displaystyle \v \in M_L} such that Failed to parse (unknown function "\u"): {\displaystyle \u+\v=\0}
  5. Failed to parse (unknown function "\u"): {\displaystyle a \bullet (b \bullet \u) = (a \bullet b) \bullet \u} for all and Failed to parse (unknown function "\u"): {\displaystyle \u \in M_L}
  6. Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikiversity.org/v1/":): {\displaystyle a \bullet (\u+\v) = (a \bullet\u) + (a \bullet \v)} for all and Failed to parse (unknown function "\u"): {\displaystyle \u,\v \in M_L}
  7. Failed to parse (unknown function "\u"): {\displaystyle (a + b) \bullet \u = (a \bullet \u) + (b \bullet \u)} for all and Failed to parse (unknown function "\u"): {\displaystyle \u \in M_L}

A right module is analogously defined to except for two things that are different in its definition:

  1. the morphism "" goes from to and
  1. the scalar multiplication operations act on the right of the elements.

An R-module generalizes the concept of module to -objects by employing Mitchell's definition of a "ring with n-objects" ; thus an -module is in fact an module with this notation.

Remarks

[edit | edit source]

One can define the categories of left- and - right R-modules, whose objects are, respectively, left- and - right R-modules, and whose arrows are R-module morphisms.

If the ring is commutative one can prove that the category of left --modules and the category of right --modules are equivalent (in the sense of an equivalence of categories, or categorical equivalence).