I've written a rudimentary algorithm in Fortran 95 to calculate the gradient of a function (an example of which is prescribed in the code) using central differences augmented with a procedure known as Richardson extrapolation.
function f(n,x) ! The scalar multivariable function to be differentiated integer :: n real(kind = kind(1d0)) :: x(n), f f = x(1)**5.d0 + cos(x(2)) + log(x(3)) - sqrt(x(4)) end function f !=====! !=====! !=====! program gradient !==============================================================================! ! Calculates the gradient of the scalar function f at x=0using a finite ! ! difference approximation, with a low order Richardson extrapolation. ! !==============================================================================! parameter (n = 4, M = 25) real(kind = kind(1d0)) :: x(n), xhup(n), xhdown(n), d(M), r(M), dfdxi, h0, h, gradf(n) h0 = 1.d0 x = 3.d0 ! Loop through each component of the vector x and calculate the appropriate ! derivative do i = 1,n ! Reset step size h = h0 ! Carry out M successive central difference approximations of the derivative do j = 1,M xhup = x xhdown = x xhup(i) = xhup(i) + h xhdown(i) = xhdown(i) - h d(j) = ( f(n,xhup) - f(n,xhdown) ) / (2.d0*h) h = h / 2.d0 end do r = 0.d0 do k = 3,M r(k) = ( 64.d0*d(k) - 20.d0*d(k-1) + d(k-2) ) / 45.d0 if ( abs(r(k) - r(k-1)) < 0.0001d0 ) then dfdxi = r(k) exit end if end do gradf(i) = dfdxi end do ! Print out the gradient write(*,*) " " write(*,*) " Grad(f(x)) = " write(*,*) " " do i = 1,n write(*,*) gradf(i) end do end program gradient
In single precision it runs fine and gives me decent results. But when I try to change to double precision as shown in the code, I get an error when trying to compile claiming that the assignment statement
d(j) = ( f(n,xhup) - f(n,xhdown) ) / (2.d0*h)
is producing a type mismatch
real(4)/real(8). I have tried several different declarations of double precision, appended every appropriate double precision constant in the code with
d0, and I get the same error every time. I'm a little stumped as to how the function
f is possibly producing a single precision number.