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If <math>\phi</math> is a homomorphism from ''G'' to ''H'' and <math>\sigma</math> is a homomorphism from ''H'' to ''K'', show that <math>\sigma\phi</math> is a homomorphism from ''G'' to ''K''.
 
If <math>\phi</math> is a homomorphism from ''G'' to ''H'' and <math>\sigma</math> is a homomorphism from ''H'' to ''K'', show that <math>\sigma\phi</math> is a homomorphism from ''G'' to ''K''.
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for this problem you need to show that <math>\sigma</math>(<math>\phi</math>(a*b))=<math>\sigma</math>(<math>\phi</math>(a))*<math>\sigma</math>(<math>\phi</math>(b)).
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The left hand side is in G and the right is in K.  To prove this you must show a middle step that is created in H by applying the <math>\phi</math> to a*b to get <math>\sigma</math>(<math>\phi</math>(a*b))=<math>\sigma</math>(<math>\phi</math>(a)*<math>\phi</math>(b)).
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Similarly, the same property can be applied to get to the final step.
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--[[User:Podarcze|Podarcze]] 12:12, 18 February 2009 (UTC)

Latest revision as of 07:12, 18 February 2009


If $ \phi $ is a homomorphism from G to H and $ \sigma $ is a homomorphism from H to K, show that $ \sigma\phi $ is a homomorphism from G to K.



for this problem you need to show that $ \sigma $($ \phi $(a*b))=$ \sigma $($ \phi $(a))*$ \sigma $($ \phi $(b)).

The left hand side is in G and the right is in K. To prove this you must show a middle step that is created in H by applying the $ \phi $ to a*b to get $ \sigma $($ \phi $(a*b))=$ \sigma $($ \phi $(a)*$ \phi $(b)).

Similarly, the same property can be applied to get to the final step. --Podarcze 12:12, 18 February 2009 (UTC)

Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva