Repository designed to maintain fortran scripts for numerical analysis.

The file numerical_analysis.F95, contains the following functions:

Some functions must be edited to include the equations necessary for the analysis, such as the differential equations that must be included in the functions before executing them.

• Linear Systems

  • Gaussian Elimination

        GaussianElimination(Matrix, m, V)
    
    ! Matrix - System Matrix (real*8, dimension(m,m))
    ! m      - Matrix Order (integer)
    ! V      - independent values (real*8, dimension(m))
    ! Returns a real*8 vector of size m
    

  • Tridiagonal Systems

        Tridiagonal(a, b, c, d, order)
    
    ! a, b ,c  - system vectors (real*8, dimension(order))
    ! d        - independent values (real*8, dimension(order))
    ! order    - system order (integer)
    ! Returns a real*8 vector of size order
    

• Interpolation Methods

  • Newton Interpolator Polynomial

        Newton(x, y, n, ent)
    
    ! x, y - Domain and Image (real*8, dimension(n))
    ! n    - Vectors Size (integer)
    ! ent  - Value to Interpolate (real*8)
    ! Returns real*8 value
    

  • Lagrange Interpolator Polynomial

        Lagrange(x, y, n, ent)
    
    ! x, y - Domain and Image (real*8, dimension(n))
    ! n    - Vectors Size (integer)
    ! ent  - Value to Interpolate (real*8)
    ! Returns real*8 value
    

  • Gregory Newton Interpolator Polynomial

        GregoryNewton(x, y, n, ent)
    
    ! x, y - Domain and Image (real*8, dimension(n))
    ! n    - Vectors Size (integer)
    ! ent  - Value to Interpolate (real*8)
    ! Returns real*8 value
    

• Differential Equations

  • Euler Method

        Euler(a, b, h, alf)
    
    ! a, b - domain range (real*8)
    ! h    - step (real*8)
    ! alf  - initial value of Y'(x,y) (real*8)
    ! Returns an array [ real*8 array(n+2,2) ]
    

  • Second-order Runge Kutta

        RungeKutta2(a, b, h, alf)
    
    ! a, b - domain range (real*8)
    ! h    - step (real*8)
    ! alf  - initial value of Y'(x,y) (real*8)
    ! Returns an array [ real*8 array(n+2,2) ]
    

  • Fourth-order Runge Kutta

        RungeKutta4(a, b, h, alf)
    
    ! a, b - domain range (real*8)
    ! h    - step (real*8)
    ! alf  - initial value of Y'(x,y) (real*8)
    ! Returns an array [ real*8 array(n+2,2) ]
    

  • Runge Kutta method for systems of differential equations

        RungeKuttaSist(a, b, alf1, alf2, h)
        
    ! a, b - domain range (real*8)
    ! h    - step (real*8)
    ! alf1, alf2  - initial value of Y1'(x) e Y1'(x) (real*8)
    ! Returns an array [ real*8 array(n+1,3) ]
    

• Numerical Integration

  • Trapezoid Rule

        TrapezoidalRule(a, b, h)
    
    ! a, b - Integration limits (real*8)
    ! h    - domain range / precision (real*8)
    ! Returns real*8 value
    

  • Discreet Trapezoid Rule

        DiscreetTrapezoidal(x, y, a, b,  h, n)
    
    ! x, y - domain and function image (real*8, dimension(n) )
    ! a, b - Integration limits (real*8)
    ! h    - domain range (real*8)
    ! n    - vector size (integer)
    ! Returns real*8 value
    

  • Gaussian Quadrature

        GaussianQuadrature(a, b, n)
    
    ! a, b - Integration limits (real*8)
    ! n    - Degree of integration (integer)
    ! Returns real*8 value
    

  • Simpson method (3/8 Rule)

        Simpson(a, b, n)
    
    ! a, b - Integration limits (real*8)
    ! n    - Degree of integration (integer)
    ! Returns real*8 value
    

To compile run the following command:

gfortran main.F95 numerical_analysis.F95

The main.F95 file, for example, is the file that makes use of the functions.