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01/24/2016 05:31:52 AM · #27401 |
my jimmies have a nice pattern, will they do ?
a win for the pair of them |
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01/24/2016 05:51:33 PM · #27402 |
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01/24/2016 06:06:42 PM · #27403 |
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01/26/2016 09:48:18 AM · #27404 |
| Its about that time of the day again... |
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01/26/2016 04:51:37 PM · #27405 |
| daylight come and I want go home |
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01/26/2016 05:04:49 PM · #27406 |
| good bye till next we meet |
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01/27/2016 06:14:10 AM · #27407 |
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01/29/2016 08:05:34 AM · #27408 |
| A win of the highest order is mine. |
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01/29/2016 08:21:26 AM · #27409 |
| That is the highest odor. You really rank. |
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01/29/2016 09:14:28 AM · #27410 |
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01/29/2016 12:18:15 PM · #27411 |
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01/29/2016 12:27:55 PM · #27412 |
Tiny's RANK! Or does he "rank"?
What's the difference, people?
Even when he's slumped atop
the church, he ain't no steeple. |
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01/29/2016 02:01:54 PM · #27413 |
| Its kind of like putting lipstick on a pig.... At the end of the day its still a pig.... Or is it???? |
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01/29/2016 05:29:13 PM · #27414 |
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01/29/2016 11:40:48 PM · #27415 |
| An utter whining moaning. Whey cup. |
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01/30/2016 09:18:52 AM · #27416 |
Yes but " what's university "
I love to win on |
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01/31/2016 12:50:37 AM · #27417 |
| Let T be a tree of order k, and let G be a graph with d(G) >= k - 1 (where d(G) signifies the minimum degree of any of the vertices of G). I would like to show that G contains a subgraph isomorphic to T. |
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02/01/2016 02:25:40 PM · #27418 |
No simple graph exists. When we consider the degree sequence and the removal of vertices,
we would have (4, 4, 4, 2, 2) → (3, 3, 1, 1) → (2, 0, 0). This would leave a vertex of degree 2,
but no vertices for it to be adjacent to.
We could have a multigraph, however. If we suppose that each vertex of degree 4 had a loop,
then the removal of those loops would leave us with a degree sequence (2, 2, 2, 2, 2), which is
the sequence for C5. |
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02/01/2016 03:36:34 PM · #27419 |
| You can't have a simple graph of order 5 with those degree sequences. K5 with any one edge removed would have degree sequences (4, 4, 4, 3, 3). You can't remove any more edges without decrementing the degree of one of the vertices of order 4 (multigraphs notwithstanding). |
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02/04/2016 09:38:29 AM · #27420 |
Originally posted by bvy:
Let T be a tree of order k, and let G be a graph with d(G) >= k - 1 (where d(G) signifies the minimum degree of any of the vertices of G). I would like to show that G contains a subgraph isomorphic to T. |
For k = 1, and k = 2, the trees K1 and K2 are subgraphs of every non-empty graph. For k > 2, let T' be a tree of order k - 1, and G' a graph with d(G') >= k - 2, and suppose T' is a subgraph of G'. We proceed by induction on k.
Let T be a tree of order k, and G be a graph with d(G) >= k - 1. For some edge uv in T, such that v is a leaf node, consider T - v. T - v has order k - 1, and so it is the subgraph of some graph G with d(G) >= k - 1 >= k -2. The vertex u in T then corresponds to some u' in G. deg(u) <= k - 2 in T , and deg(u') >= k -1 in G, therefore u' must be adjacent to some v' in G not in T. As such, T is a subgraph of G.
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02/04/2016 08:36:22 PM · #27421 |
| Tomorrow I would like to show that every subgraph of a connected tree is also an induced subgraph. |
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02/04/2016 09:02:29 PM · #27422 |
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02/04/2016 09:11:07 PM · #27423 |
Originally posted by bvy:
Tomorrow I would like to show that every subgraph of a connected tree is also an induced subgraph. |
I should qualify: every connected subgraph... |
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02/05/2016 08:57:42 AM · #27424 |
Originally posted by bvy:
Originally posted by bvy:
Tomorrow I would like to show that every subgraph of a connected tree is also an induced subgraph. |
I should qualify: every connected subgraph... |
This is a fairly straightforward result. Let T' be a connected subgraph of some tree T, and suppose T' is not an induced subgraph. Then for some vertices u and v in T', the edge uv exists in T but not in T'. However if we add the edge uv to T', we've created a cycle in T' implying there is a cycle in T, which contradicts the supposition that T is a tree. Therefore every connected subgraph of a tree is also an induced subgraph. |
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02/05/2016 08:58:24 AM · #27425 |
Originally posted by kawesttex:
hi |
Hello. |
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