110 NUMERIC ALGORITHMS
If we divide p(x) by x^4 + 5, we will get a quotient and remainder polynomials,
and those are the values of q(x) and r(x), respectively. So, we need to divide as
follows:
This gives the equation
But we can apply this process to each of the polynomials for q(x) and r(x):
The results of all of this would be
If we look at this polynomial, we will see that there is one multiplication to
calculatex^2 and another to calculate x^4 (done as x^2 *x^2 ). There are also three
additional multiplications done in the equation, for a total of five multiplica-
tions. There are 10 additions done in this equation as well. Comparing this to
the other methods, we get the table in Fig. 4.1. This doesn’t look like a great
saving, but this is just for a limited case. We can get a general equation for the
amount of work done by looking carefully at the process. We first notice that
we do only one multiplication and two additions in Equation 4.3. This gives
the following set of recurrence relations for the number of multiplications,
M(k), and the number of additions, A(k), where N = 2k 1:
) x (^7) 4 x (^6) 0 x (^5) 8 x (^4) 6 x (^3) 09 x (^2) 2 x 03
x^7 4 x^6 0 x^5 8 x^4 5 x^3 20 x^2 0 x 40
x^3 11 x^2 2 x 37
x^3 04 x^2 0 x 08
x^4 5
px()= ()x^4 + (^5) ()x^3 +++ 4 x^20 x 8 +()x^3 – 11 x^2 + 2 x– 37
x 14
) x (^3) 4 x (^2) 0 x 18 )
x^3 4 x^2 0 x 14
x^2 1
x 12
x^3 11 x^2 2 x 37
x 11
x^3 11 x^2 2 x 11
x^2 1
x 26
px()=()x^4 + (^5) []()x^2 – 1 ()x+ 4 +()x+ 12 +[]()x^2 + 1 ()x– 11 +()x– 26
M() 1 = 0
Mk()= 2 Mk()– 1 +1 for k> 1
A() 1 = 0
Ak()= 2 Ak()– 1 +2 for k> 1