The easiest, and probably best-optimized way of doing this is letting someone else do that – Xilinx has an IP core that can do that; it's the LogiCore CORDIC.

You might also want to look at logarithm implementations (e.g. log2, or anything that converts your fixed point number to floating point); Sylvain Munaut wrote one; applying basic math, using the logarithm *log_b* to the base *b*:

*sqrt(x) = b^(log_b(x)/2) = b^(y/2) = b^z*

You could do the *y/2* operation with a DSP slice, or just by bitshift. *2^z* is a bit more tricky, but in reality it boils down to shifting `0b10`

by the integral part of *z*, and multiplying that with a looked-up version of *2* to the power of the fractional part.

If you can live with being really inaccurate, how about just roughly approximating the *log_2* of a number by the position of the highest non-zero binary digit, and then using a lookup table to convert to a square root.

Assuming you can do the finding of the highest digit in two cycles, and the lookup and output generation in the next, you'd have a three cycle implementation; it'd still be very sensible to pipeline this instead of building a humongous mux chain.

`sqrt`

in embedded contexts. FPGAs give you tremendous degrees of freedom, and obviously the advice to do this in the most FPGA-y way possible would be to design circuits that implement one of these fast methods to a decent approximation. There are also methods that are assisted by lookup tables, requiring some bytes of what mounts to ROM storage. – Nick Oct 8 '15 at 18:22