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Brief Review of Proof Techniques

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Given a tree with k 1 vertices, TK 1, we know that every tree has at least two leaves. ... Adding the edge e back, Tk 1 has (k - 1) 1 = k = (k 1) 1 edges. 11 ... – PowerPoint PPT presentation

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Title: Brief Review of Proof Techniques


1
Brief Review of Proof Techniques

2
What is a proof?
A theorem is a proven mathematical statement. A
proof is a sequence of statements that form an
argument (to prove sth, say a theorem).
3
Three general methods
Proof by a direct argument. Proof by
contradiction. Proof by induction.
4
Three general methods
Proof by a direct argument. With this method, you
try to find the core of the proof and then use a
direct mathematical argument.
5
Three general methods
Proof by a direct argument. With this method, you
try to find the core of the proof and then use a
direct mathematical argument. Example. Theorem.
Svdeg(v) is even.
6
Three general methods
Proof by a direct argument. With this method, you
try to find the core of the proof and then use a
direct mathematical argument. Example. Theorem.
Svdeg(v) is even. Proof. Let eltu,vgt be any edge
in the graph. When counting deg(u) and deg(v), e
is counted once each time. Therefore, each edge e
contributes 2 to Svdeg(v). Therefore,
Svdeg(v)2E, which is always even. ?

7
Three general methods
Proof by a direct argument. With this method, you
try to find the core of the proof and then use a
direct mathematical argument. Example. Theorem. A
tree with n nodes has n-1 edges.
8
Three general methods
Proof by a direct argument. With this method, you
try to find the core of the proof and then use a
direct mathematical argument. Example. Theorem. A
tree T with n nodes has n-1 edges. Proof. Let
TTn. We know that each tree has at least 2
leaves. So we delete a leave node as well as the
edge incident to it to obtain Tn-1, which is
again a tree. We can repeat this process n-2
times (delete one node for one edge) until we
have T2, which has only one edge. Clearly, Tn has
(n-2)1n-1 edges. ?
9
Three general methods
Proof by contradiction. With this method, you
assume that the statement you want to prove is
not true. Then you try to obtain a contradiction
(either with the definition or some known
facts). Example. Theorem. A tree T with n nodes
has n-1 edges.
10
Three general methods
Proof by contradiction. With this method, you
assume that the statement you want to prove is
not true. Then you try to obtain a contradiction
(either with the definition or some known
facts). Example. Theorem. A tree T with n nodes
has n-1 edges. Proof. Assume that T doesnt have
n-1 edges. So it can contain either gtn-1 edges or
ltn-1 edges. If it has more than n-1 edges, then T
must contain a cycle. If it has less than n-1
edges, then T is disconnected. In either cases,
we have a contradiction as by definition T is a
connected acyclic graph.
?
11
Three general methods
Proof by contradiction. With this method, you
assume that the statement you want to prove is
not true. Then you try to obtain a contradiction
(either with the definition or some known
facts). Example. Theorem. v2 is irrational.
12
Three general methods
Proof by contradiction. With this method, you
assume that the statement you want to prove is
not true. Then you try to obtain a contradiction
(either with the definition or some known
facts). Example. Theorem. v2 is
irrational. Proof. Assume that v2 is rational. By
definition v2m/n, with m,n being integers and
gcd(m,n)1. Square both sides of v2m/n, we have
2n2m2 . Then m must be even. Let m2k. We have
2n2(2k)24k2. Then n22k2, so n is even
as well. Then gcd(m,n)?1. A contradiction.
?
13
Three general methods
Proof by induction. With this method, you have to
check the Basis, then make an assumption that the
claim (to be proven) is true up to certain k and
finally you should that the claim is still true
for k1. This method usually can only be used to
prove claims related to natural numbers. Example.
Theorem. A tree T with n nodes has n-1 edges.
14
Three general methods
Proof by induction. With this method, you have to
check the Basis, then make an assumption that the
claim (to be proven) is true up to certain k and
finally you should that the claim is still true
for k1. This method usually can only be used to
prove claims related to natural numbers. Example.
Theorem. A tree T with n nodes has n-1
edges. Proof. Basis. When n1, T has n-10 edges.
So the claim is correct. Inductive Hypothesis.
Assume that the claim is true for all T with k
vertices. Inductive Step. Given a tree with k1
vertices, TK1, we know that every tree has at
least two leaves. So by pruning a leave node and
its incident edge e from Tk1, we obtain another
tree T with k vertices. By IH, T has k-1 edges.
Adding the edge e back, Tk1 has (k - 1)1 k
(k1) 1 edges. ?
15
Three general methods
Proof by induction. With this method, you have to
check the Basis, then make an assumption that the
claim (to be proven) is true up to certain k and
finally you should that the claim is still true
for k1. This method usually can only be used to
prove claims related to natural numbers. Example.
Theorem. 1323n3n2(n1)2/4. Proof. Basis.
When n1, 1312(11)2/41. Inductive Hypothesis.
Assume that 1323k3k2(k1)2/4. Inductive
Step. 1323k3(k1)3k2(k1)2/4 (k1)3
k2/4(k1)(k1)2 (k1)2(k2)2/4 (k1)2(k1)
12/4 ?
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