1.1 Induction
1. In each case we give the equation that makes pk imply pk+1.
a. k(2k−1)+(4k+1)=2k2+3k+1=(k+1)(2k+1)
c. 
e. 
g. 
7
7
i. 
2. In each case we give the inequality that makes pk imply pk+1.
a. 2k+1=2·2k>2·k≥k+1.
c. If 
, then 
provided k+1≤22k+1. This latter inequality follows, again by induction on k≥1, because 22k+3=4·22k+1≥4(k+1)≥k+2.
, then provided k+1≤22k+1. This latter inequality follows, again by induction on k≥1, because 22k+3=4·22k+1≥4(k+1)≥k+2.
e. 
.
.
3. In each case we give the calculation that makes pk imply pk+1.
a. If k3+(k+1)3+(k+2)3=9m, then (k+1)3 + (k+2)3 + (k+3)3 = 9m−k3 + (k+3)3 = 9m+9k2 + 27k + 27.
c. If 32k+1+2k+2=7m, then
5. If 33k+1=7m where k is odd, then passing to ...
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