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I think this is the right way to do it.  At least, it makes sense to me, and it was the track I was on before I logged in to Rhea.
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I think this is the right way to do it.  At least, it makes sense to me, and it was the track I was on before I logged in to Rhea.  Maybe we're both wrong.
 
-Tim
 
-Tim

Revision as of 16:51, 24 September 2008

This is how I went about the problem...it may be completely wrong, so please correct me if I am solving the problem in the completely incorrect manner. It made sense in my head though. Here we go...

Because group G is of order 155 and a and b are non identity elements of different orders in group G, we have:

155 = |G| = |a|k_1, for some k_1 > 0

155 = |G| = |b|k_2, for some k_2 > 0

Since a and b are non identity elements, |a| /= 1 /= b (not equal...sorry, don't know the code) Also, since 155 = 31 * 5 and a and b are both of a different order, |a| = k_2 and |b| = k_1, so 155 = |a|*|b| = |G|. Thus the only subgroup of G that can contain both a and b is G itself. //

Is this logical?


I think this is the right way to do it. At least, it makes sense to me, and it was the track I was on before I logged in to Rhea. Maybe we're both wrong. -Tim

Alumni Liaison

Basic linear algebra uncovers and clarifies very important geometry and algebra.

Dr. Paul Garrett