1.6 RECURRENCE RELATIONS 35
indicates that we would have substituted five times, would have six terms
based on 15, and would have 2^6 for the coefficient of T(2). If you look
closely at the last equation and substitute 14 in for n, you will see that this is
exactly what we have.
What if n is an odd number? Will these formulas still work? Let’s consider
ann value of 13. In the above equation, the only thing that would change is
thatT would have a value of 1 instead of 2, but by our equations, n / 2 1 is
5 (not 6) when n is 13. For odd n, we will use n / 2 instead of n / 2 1. We
will have two cases in our answer.
Now, applying Equation 1.17, for an even value of n we get
and, if n is odd, we get
Consider another recurrence relation:
We will proceed in the same way as we did in the previous example. We first
substitute in a set of values for n, only in this case, because n is being divided
Tn() 2 ()n⁄^2 –^1 T() 2 15 2 i ifn is even
i=0
()n⁄ 2 – 1
= – ∑ Tn() 2 n⁄^2 T() 1 15 2 i ifn is odd
i=0
n⁄ 2
= – ∑
Tn() 2 ()n⁄^2 –^1 * 40 15 2 i ifn is even
i=0
()n⁄ 2 – 1
= – ∑ Tn() 2 n⁄^2 * 40 15 2 i ifn is odd
i=0
n⁄ 2
= – ∑
Tn()= 2 ()n⁄^2 –^1 * 40 15– * () 2 n⁄^2 – 1
= 2 n⁄^2 * 20 2– n⁄^2 * 15 15+
= 2 n⁄^2 ()20 15– + 15
= 2 n⁄^2 * 515 +
Tn()= 2 n⁄^2 * 40 15– * () 2 ()n⁄^2 +^1 – 1
= 2 n⁄^2 * 40 2– n⁄^2 * 30 + 15
= 2 n⁄^2 ()40 30– + 15
= 2 n⁄^2 * 10 15+
Tn()^5 if n≤^4
^4 Tn()⁄^2 –^1 otherwise
=