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Directory:Jon Awbrey/Papers/Differential Logic (view source)

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==Note 21==

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To construct the regular representations of <math>S_3,\!</math> we begin with the data of its operation table:

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{| align="center" cellpadding="6" width="90%"

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| align="center" |

<pre>

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~~To construct the regular representations of S_3,~~

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~~we pick up from the data of its operation table:~~

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Table 1. Symmetric Group S_3

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o-------------------------------------------------o

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| |

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| ^ |

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| e / \ e |

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| / \ |

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| / e \ |

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| f / \ / \ f |

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| / \ / \ |

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| / f \ f \ |

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| g / \ / \ / \ g |

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| / \ / \ / \ |

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| / g \ g \ g \ |

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| h / \ / \ / \ / \ h |

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| / \ / \ / \ / \ |

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| / h \ e \ e \ h \ |

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| i / \ / \ / \ / \ / \ i |

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| / \ / \ / \ / \ / \ |

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| / i \ i \ f \ j \ i \ |

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| j / \ / \ / \ / \ / \ / \ j |

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| / \ / \ / \ / \ / \ / \ |

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| ( j \ j \ j \ i \ h \ j ) |

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| \ / \ / \ / \ / \ / \ / |

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| \ / \ / \ / \ / \ / \ / |

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| \ h \ h \ e \ j \ i / |

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| \ / \ / \ / \ / \ / |

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| \ / \ / \ / \ / \ / |

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| \ i \ g \ f \ h / |

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| \ / \ / \ / \ / |

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| \ / \ / \ / \ / |

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| \ f \ e \ g / |

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| \ / \ / \ / |

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| \ / \ / \ / |

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| \ g \ f / |

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| \ / \ / |

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| \ / \ / |

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| \ e / |

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| \ / |

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| \ / |

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| v |

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| |

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o-------------------------------------------------o

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</pre>

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|}

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~~| ^~~

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Just by way of staying clear about what we are doing, let's return to the recipe that we worked out before:

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~~| e / \ e~~

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~~| / \~~

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~~| / e \~~

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~~| f / \ / \ f~~

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~~| / \ / \~~

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~~| / f \ f \~~

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~~| g / \ / \ / \ g~~

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~~| / \ / \ / \~~

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~~| / g \ g \ g \~~

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~~| h / \ / \ / \ / \ h~~

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~~| / \ / \ / \ / \~~

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~~| / h \ e \ e \ h \~~

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~~| i / \ / \ / \ / \ / \ i~~

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~~| / \ / \ / \ / \ / \~~

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~~| / i \ i \ f \ j \ i \~~

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~~| j / \ / \ / \ / \ / \ / \ j~~

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~~| / \ / \ / \ / \ / \ / \~~

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~~| ( j \ j \ j \ i \ h \ j )~~

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~~| \ / \ / \ / \ / \ / \ /~~

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~~| \ / \ / \ / \ / \ / \ /~~

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~~| \ h \ h \ e \ j \ i /~~

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~~| \ / \ / \ / \ / \ /~~

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~~| \ / \ / \ / \ / \ /~~

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~~| \ i \ g \ f \ h /~~

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~~| \ / \ / \ / \ /~~

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~~| \ / \ / \ / \ /~~

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~~| \ f \ e \ g /~~

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~~| \ / \ / \ /~~

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~~| \ / \ / \ /~~

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~~| \ g \ f /~~

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~~| \ / \ /~~

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~~| \ / \ /~~

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~~| \ e /~~

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~~| \ /~~

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~~| \ /~~

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~~| v~~

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~~Just by way~~ of ~~staying clear about what~~ we ~~are doing,~~

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It is part of the definition of a group that the 3-adic relation <math>L \subseteq G^3</math> is actually a function <math>L : G \times G \to G.</math> It is from this functional perspective that we can see an easy way to derive the two regular representations.

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~~let's return~~ to the ~~recipe that we worked out before:~~

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~~It is part~~ of the ~~definition of a group that the 3-adic~~

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Since we have a function of the type <math>L : G \times G \to G,</math> we can define a couple of substitution operators:

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~~relation~~ L c G~~^3 is actually a function L :~~ G x G -> G.

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~~It is from this functional perspective that~~ we can ~~see~~

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~~an easy way to derive the two regular representations.~~

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~~Since we have a function of the type L : G x G -~~> G,

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# <math>\operatorname{Sub}(x, (\underline{~~}, y))</math> puts any specified <math>x\!</math> into the empty slot of the rheme <math>(\underline{~~}, y),</math> with the effect of producing the saturated rheme <math>(x, y)\!</math> that evaluates to <math>x \cdot y.</math>

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~~we can define a couple of substitution operators:~~

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# <math>\operatorname{Sub}(x, (y, \underline{~~}))</math> puts any specified <math>x\!</math> into the empty slot of the rheme <math>(y, \underline{~~}),</math> with the effect of producing the saturated rheme <math>(y, x)\!</math> that evaluates to <math>y \cdot x.</math>

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1. Sub(x, <_, y>) puts any specified x into

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the empty slot of the rheme <_, y>, with

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the effect of producing the saturated

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rheme <x, y> that evaluates to ~~x·y~~.

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2. Sub(x, <y, _>) puts any specified x into

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the empty slot of the rheme <y, >, with

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the effect of producing the saturated

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rheme <y, x> that evaluates to ~~y·x~~.

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<pre>

In (1), we consider the effects of each x in its

practical bearing on contexts of the form <_, y>,

Jon Awbrey

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