I am trying to divide two numbers, a numerator N by a divisor D. I am using the Newton–Raphson method which uses Newton's method to find the reciprocal of D (1/D). Then the result of the division can be found by multiplying the numerator N by the reciprocal 1/D to get N/D.
The Newton-Raphson algorithm can be found here
So the first step of the algorithm is to start with an initial guess for 1/D which we call X_0.
X_0 is defined as X_0 = 48/17-39/17*D
However, we must first apply a bit-shift to the divisor D to scale it so that 0.5 ≤ D ≤ 1. The same bit-shift should be applied to the numerator N so that the quotient does not change.
We then find X_(i+1) using the formula X_(i+1) = X_i*(2-D*X_i)
Since both the numerator N, divisor D, and result are all floating point IEEE-754 32-bit format, I am wondering how to properly apply this scaling since my value for 1/D does not converge to a value, it just approaches -Inf or +Inf (depending on D).
What I have found works though is that if I make X_0 less than 1/D, the algorithm seems to always converge. So if I just use a lookup table where I always store a bunch of values of 1/D and I can always ensure I have a stored 1/D value where D > Dmin, then I should be okay. But is that standard practice?