Revision as of 11:33, 12 April 2015 edit 86.127.138.67 (talk) →Examples: this is an even more basic example than cosets, except is more obscure because even transformation semigroups are seldom discussed in general algebra texts... Someone should add a pretty picture with the quasi-inverses in color. ← Previous edit		Revision as of 11:34, 12 April 2015 edit undo 86.127.138.67 (talk) →Examples Next edit →
Line 10: In general, since any [[equivalence relation]] on an arbitrary set gives rise to a partition, picking any representative from each [[equivalence class]] results in a transversal. Another instance of this partition-induced transversal occurs when one considers the equivalence relation known as the [[Kernel (set theory)\|(set-theoretic) kernel of a function]]: : <math>\operatorname{ker} f := \{(x,y) \mid f(x) = f(y)\}</math>. If ''f'' is injective, a transversal of <math>\operatorname{ker} f</math> is unique. In general, for a fixed transversal ''T'' of <math>\operatorname{ker} f</math>, every ''z'' in the [[Image_%28mathematics%29#Image_of_a_function\|image]] of ''f'' is one-to-one correspondence with exactly one element ''x'' of ''T'', thus a function ''g'' with the property that for all ''x'' in ''T'', <math>g(z) = x</math> with <math>f(x)=z</math> is well defined by picking some arbitrary values for the rest of the points in ''g'''s ___domain. Furthermore a <math>f\circ ~~g_T~~g \circ f = f</math>, which is the proof (when ___domain an codomain of ''f'' and ''g'' are the same set) that the [[full transformation semigroup]] is a [[regular semigroup]]. <math>~~g_T~~g</math> acts as a (not necessarily unique) [[Inverse_element#In_a_semigroup\|quasi-inverse]]; within semigroup theory this is simply called an inverse. Note however that for an arbitrary ''g'' with the aforementioned property the "dual" equation <math>g \circ f \circ g= g</math> may not hold. However if we denote by <math>h= g \circ f \circ g</math>, then ''f'' is a quasi-inverse of ''h'', i.e. <math>h \circ f \circ h = h</math>. <!-- this calculation is rather hard to follow without a picture, so I'm not sure it adds much as it is As a concrete instance, if <math>f: \{1,2,3\} \to \{1,2,3\}</math> is the non-bijective mapping <math>f(1) = 2, f(2)=2, f(3)=3</math>, then its kernel is <math>\operatorname{ker} f = \{ \{1,2\}, \{3\} \}</math>. A transversal of <math>\operatorname{ker} f</math> is <math>T_1 = \{ \{1\}, \{3\} \}</math> and another transversal is <math>T_2 = \{ \{2\}, \{3\} \}</math>. Fixing <math>T_1</math> as the choice of transversal, a function <math>g</math> induced by <math>T_1</math> must have the property that <math>g(2) = 1</math> and <math>g(3) = 3</math>; however the transversal <math>T_1</math> does not constrain where ''g'' maps 1. Nevertheless, it can be verified that ''g'' has the desired quasi-inverse role relative to ''f'': <math>f(g(f(1))) = f(g(2)) = f(1)</math>, <math>f(g(f(2))) = f(g(2)) = f(1) = 2 = f(2)</math>, <math>f(g(f(3))) = f(g(3)) = f(3)</math>. Note that <math>g(1)</math> did not appear in these calculations. One could choose <math>g(1)=2</math>, a choice that makes ''g'' bijective; therefore, we expect that <math>g \circ f \circ g = h \neq g</math>. And indeed <math>h(1) = g(f(g(1)))=1\neq 2 = g(1)</math>. However <math>h(f(h(1)))=h(f(1))=h(2)=g(f(g(2))= g(2)=1</math> is compatible with the role of ''f'' as quasi-inverse of ''h''.

Transversal (combinatorics): Difference between revisions