Prove that 2^{n+1}>(n+2) cdot sin(n) for all positive integers n.

albiguguiismx

albiguguiismx

Answered question

2022-09-04

Prove that 2 n + 1 > ( n + 2 ) sin ( n ) for all positive integers n.
Proof: If P(n) represents the given proposition.
(1) Basic Step: P(n) for n = 1 is
2 1 + 1 > ( 1 + 2 ) sin ( 1 )
2 2 > 3 sin ( 1 )
4 > 3 sin ( 1 )
Since sin ( n ) 1 and 1 < 4 / 3 and so sin ( n ) < 4 / 3 by putting n = 1, we obtain
sin ( 1 ) < 4 / 3 4 > 3 sin ( 1 )
Which is true.
(2) Induction Step: Suppose that P(n) is true for n = k, i.e. Let
2 k + 1 > ( k + 2 ) sin ( k )
To prove that P(n) to be true for n = k + 1
2 ( k + 1 ) + 1 = 2 k + 1 2 = 2 2 k + 1 > 2 ( k + 2 ) sin ( k )
How to prove P(n) to be true for n = k + 1. I got stuck here. Would appreciate for your assistance. Also review my proof if there is any mistake while writing.

Answer & Explanation

Emma Cooper

Emma Cooper

Beginner2022-09-05Added 9 answers

Step 1
Here classical induction needs some modification.
Show that it is true for n = 1
Step 2
Since n + 2 ( n + 2 ) sin n, it suffices to show that
2 n + 1 > n + 2
for n 2, which can be inductively.

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