What is the motivation for defining PI as
PI=4.D0*DATAN(1.D0)
within a Fortran 77 code? I understand how it works, but, what is the reasoning?
We started with Q&A. Technical documentation is next, and we need your help.
Whether you're a beginner or an experienced developer, you can contribute.

This style ensures that the maximum precision available on ANY architecture is used when assigning a value to PI. 


Because Fortran does not have a builtin constant for These are equivalent and you'll sometimes see them too:



It's because this is an exact way to compute By contrast, specifying 


I believe it's because this is the shortest series on pi. That also means it's the MOST ACCURATE. The GregoryLeibniz series (4/1  4/3 + 4/5  4/7...) equals pi. atan(x) = x^1/1  x^3/3 + x^5/5  x^7/7... So, atan(1) = 1/1  1/3 + 1/5  1/7 + 1/9... 4 * atan(1) = 4/1  4/3 + 4/5  4/7 + 4/9... That equals the GregoryLeibniz series, and therefore equals pi, approximately 3.1415926535 8979323846 2643383279 5028841971 69399373510. Another way to use atan and find pi is: pi = 16*atan(1/5)  4*atan(1/239), but I think that's more complicated. I hope this helps! (To be honest, I think the GregoryLeibniz series was based on atan, not 4*atan(1) based on the GregoryLeibniz series. In other words, the REAL proof is: sin^2 x + cos^2 x = 1 [Theorem] If x = pi/4 radians, sin^2 x = cos^2 x, or sin^2 x = cos^2 x = 1/2. Then, sin x = cos x = 1/(root 2). tan x (sin x / cos x) = 1, atan x (1 / tan x) = 1. So if atan(x) = 1, x = pi/4, and atan(1) = pi/4. Finally, 4*atan(1) = pi.) Please don't load me with commentsI'm still a preteen. 


That sounds an awful lot like a workaround for a compiler bug. Or it could be that this particular program depends on that identity being exact, and so the programmer made it guaranteed. 

