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I have been trying to compute the square root from a fixed point data-type <24,8>.
Unfortunately nothing seems to work.
Does anyone know how to do this fast and efficient in C(++)?

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5  
What exactly have you tried and what were the results? –  Djon Jun 3 '13 at 6:59
1  
Look up Newton-Raphson. Should give you a reasonable result in a just a few iterations. –  Mats Petersson Jun 3 '13 at 7:02
    
Djon, I tried the Newton-Raphson method. I Will look into this deeper! Mats Petersson thanks for the advise! –  Alex van Rijs Jun 3 '13 at 7:09

1 Answer 1

Here is a prototype in python showing how to do a square root in fixed point using Newton's method.

import math

def sqrt(n, shift=8):
     """
     Return the square root of n as a fixed point number.  It uses a
     second order Newton-Raphson convergence.  This doubles the number
     of significant figures on each iteration.

     Shift is the number of bits in the fractional part of the fixed
     point number.
     """
     # Initial guess - could do better than this
     x = 1 << shift // 32 bit type
     n_one = n << shift // 64 bit type
     while 1:
         x_old = x
         x = (x + n_one // x) // 2
         if x == x_old:
             break
     return x

def main():
    a = 4.567
    print "Should be", math.sqrt(a)
    fp_a = int(a * 256)
    print "With fixed point", sqrt(fp_a)/256.

if __name__ == "__main__":
    main()

When converting this to C++ be really careful about the types - in particular n_one needs to be a 64 bit type or otherwise it will overflow on the <<8 bit step. Note also that // is an integer divide in python.

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weird. Newton rapson method as i understand works as f(x) = x0 - f(x)/f'(x). I don't see that function here. I see your x0 is 1. What are you doing with n_one? Can you post some explanation of this code? –  newbie_old Jun 25 at 4:43
    
@newbie_old if you work the differential of sqrt out and plug into the equation above and simplify, you'll get x(i+1) = (x(i) + n/x(i))/2 where n is the number you are trying to square root. n_one is n shifted by the shift bits, which represents n in the fixed point world. –  Nick Craig-Wood Jun 25 at 15:02
    
but n_one is already in fixed point format no? I see you multiply that with 256 which is 1<<8 before feeding it to the function. So why again shifting by shift which is 8? –  newbie_old Jun 25 at 21:41
    
@newbie_old I see what you mean, my explanation is incorrect above. n_one is actually n * one², ie n_float << 16 so when you divide it by x which is x_float * one = x_float << 8 you get (n_float/x_float) * one = (n_float/x_float) << 8 which is correctly normalized, but with the full precision of the division. I hope that makes sense now! –  Nick Craig-Wood Jun 26 at 12:35
    
now it makes sense. –  newbie_old Jun 26 at 16:00

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