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प्रश्न
Use induction to prove that 5n+1 + 4 × 6n when divided by 20 leaves a remainder 9, for all natural numbers n
उत्तर
P(n) is the statement 5n + 1 + 4 × 6n – 9 is ÷ by 20
P(1) = 51+1 + 4 × 61 – 9
= 52 + 24 – 9
= 25 + 24 – 9
= 40 ÷ by 20
So P(1) is true
Assume that the given statement is true for n = k
(i.e) 5k + 1 + 4 × 6n – 9 is ÷ by 20
P(1) = 51+1 + 4 × 61 – 9
= 25 + 24 – 9
So P(1) is true
To prove P(k + 1) is true
P(k + 1) = `5^("k" + 1 + 1) + 4 × 6^("k" + 1 + 1) – 9`
= 5 × 5 k + 1 + 4 × 6 × 6k – 9
= 5[20C + 9 – 4 × 6k] + 24 × 6k – 9 .....[from(1)]
= 100C + 45 – 206k + 246k – 9
= 100C + 46k + 36
= 100C + 4(9 + 6k)
Now for k = 1
⇒ 4(9 + 6k)
= 4(9 + 6)
= 4 × 15 = 60 ÷ by 20 .
For k = 2
= 4(9 + 62)
= 4 × 45
= 180 ÷ 20
So by the principle of mathematical induction 4(9 + 6k) is ÷ by 20
Now 100C is ÷ by 20.
So 100C + 4(9 + 6k) is ÷ by 20
⇒ P(k + 1) is true
Whenever P(k) is true.
So by the principle of mathematical induction
P(n) is true.
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