# Why is my Lagrange interpolation algorithm not working?

For some reason it never interpolates, but it gives 0 as an answer. The code is:

``````  PROGRAM LAGRANGE
REAL X(0:100), Y(0:100), INTERP
REAL TEMP = 1.0
REAL POLINOM = 0.0
N=10
OPEN(1,FILE="datos.txt")
DO I=0,100 !We 'clean' the arrays: all positions are 0
X(I)=0.0
Y(I)=0.0
END DO
DO I=0,10 !We read the data file and we save the info
END DO
CLOSE(1)

WRITE(*,*) "Data table:"
DO I=0,10
WRITE(*,*) X(I), Y(I)
END DO

WRITE(*,*) "Which value of X do you want to interpolate?"

DO I=0,N
DO J=0,N
IF(J.NE.I) THEN !Condition: J and I can't be equal
TEMP=TEMP*(INTERP-X(J))/(X(I)-X(J))
ELSE IF(J==I) THEN
TEMP=TEMP*1.0
ELSE
END IF
END DO
POLINOM=POLINOM+TEMP
END DO

WRITE(*,*) "Value: ",POLINOM

STOP
END PROGRAM
``````

Where did I fail? I basically need to implement this:

Lagrange interpolation method

Thanks a lot in advance.

• Always use `implicit none`! Doubly so when having a problem and quadruply so when presenting the code to others but use it for the sanity of your own mind. Oct 6, 2023 at 5:01

In addition to the "symbol-concatenation" problem (explained in the other answer), it seems that `TEMP` needs to be reset to 1.0 for every `I` (to calculate the Lagrange polynomial for each grid point), plus we need to multiply it by the functional value on that point (`Y(I)`). After fixing these

``````PROGRAM LAGRANGE
implicit none  !<-- always recommended
REAL :: X(0:100), Y(0:100), INTERP, TEMP, POLINOM
integer :: I, J, K, N

N = 10
X = 0.0
Y = 0.0

!! Test data (sin(x) over [0,2*pi]).
DO I = 0, N
X(I) = real(I) / real(N) * 3.14159 * 2.0
Y(I) = sin( X(I) )
END DO

WRITE(*,*) "Data table:"
DO I = 0, N
WRITE(*,*) X(I), Y(I)
END DO

interp = 0.5   !! test value

POLINOM = 0.0
DO I = 0, N

TEMP = 1.0   !<-- TEMP should be reset to 1.0 for every I
DO J = 0, N
IF( J /= I ) THEN
TEMP = TEMP * (interp - X(J)) / (X(I) - X(J))
END IF
END DO
TEMP = TEMP * Y(I)  !<-- also needs this

POLINOM = POLINOM + TEMP
END DO

print *, "approx : ", POLINOM
print *, "exact  : ", sin( interp )
end
``````

we get a pretty good agreement between the approximate (= interpolated) and exact results:

`````` Data table:
0.00000000       0.00000000
0.628318012      0.587784827
1.25663602      0.951056182
1.88495409      0.951056957
2.51327205      0.587786913
3.14159012       2.53518169E-06
3.76990819     -0.587782800
4.39822626     -0.951055467
5.02654409     -0.951057792
5.65486193     -0.587789178
6.28318024      -5.07036339E-06
approx :   0.479412317
exact  :   0.479425550
``````

Consider the (complete) program

``````      real x = 1.
end
``````

What does this do?

If this is free-form source then it is an invalid program. If it is fixed-form source then it is a valid program.

In fixed-form source, spaces after column 6 largely have no effect. The program above is exactly like

``````      realx=1.
end
``````

and we can see that we're just setting an implicitly declared real variable called `realx` to have value `1.`. Such a statement is an assignment statement, not a type declaration statement with initialization.

Preventing implicit typing, as in

``````      implicit none
real x = 1.
end
``````

will show a problem.

In both free- and fixed-form source, initialization in a declaration statement requires `::`, like so:

``````      real :: x = 1.
end
``````

And: use `implicit none`.