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nonlin

A library that provides routines to compute the solutions to systems of nonlinear equations.

Status

CMake Actions Status

Documentation

Documentation can be found here

Building NONLIN

CMakeThis library can be built using CMake. For instructions see Running CMake.

FPM can also be used to build this library using the provided fpm.toml.

fpm build

The NONLIN library can be used within your FPM project by adding the following to your fpm.toml file.

[dependencies]
nonlin = { git = "https://github.com/jchristopherson/nonlin" }

External Libraries

Here is a list of external code libraries utilized by this library.

Example 1

This example solves a set of two equations of two unknowns using a Quasi-Newton type solver. In this example, the solver is left to compute the derivatives numerically.

program  example
    use iso_fortran_env
    use nonlin_core
    use nonlin_solve, only : quasi_newton_solver
    implicit none

    ! Local Variables
    type(vecfcn_helper) :: obj
    procedure(vecfcn), pointer :: fcn
    type(iteration_behavior) :: ib
    type(quasi_newton_solver) :: solver
    real(real64) :: x(2), f(2)

    ! Locate the routine containing the equations to solve
    fcn => fcns
    call obj%set_fcn(fcn, 2, 2)

    ! Define an initial guess
    x = 1.0d0 ! Equivalent to x = [1.0d0, 1.0d0]

    ! Defining solver parameters.  This step is optional as the defaults are
    ! typically sufficient; however, this is being done for illustration 
    ! purposes.
    !
    ! Establish how many iterations are allowed to pass before the solver
    ! forces a re-evaluation of the Jacobian matrix.  Notice, the solver may
    ! choose to re-evaluate the Jacobian sooner than this, but that is 
    ! dependent upon the behavior of the problem.
    call solver%set_jacobian_interval(20)

    ! Establish convergence criteria.  Again, this step is optional as the
    ! defaults are typically sufficient; however, this is being done for
    ! illustration purposes.
    call solver%set_fcn_tolerance(1.0d-8)
    call solver%set_var_tolerance(1.0d-12)
    call solver%set_gradient_tolerance(1.0d-12)

    ! Solve
    call solver%solve(obj, x, f, ib)

    ! Display the output
    print '(AF7.5AF7.5A)', "Solution: (", x(1), ", ", x(2), ")"
    print '(AE9.3AE9.3A)', "Residual: (", f(1), ", ", f(2), ")"
    print '(AI0)', "Iterations: ", ib%iter_count
    print '(AI0)', "Function Evaluations: ", ib%fcn_count
    print '(AI0)', "Jacobian Evaluations: ", ib%jacobian_count

contains
    ! Define the routine containing the equations to solve.  The equations are:
    ! x**2 + y**2 = 34
    ! x**2 - 2 * y**2 = 7
    subroutine fcns(x, f)
        real(real64), intent(in), dimension(:) :: x
        real(real64), intent(out), dimension(:) :: f
        f(1) = x(1)**2 + x(2)**2 - 34.0d0
        f(2) = x(1)**2 - 2.0d0 * x(2)**2 - 7.0d0
    end subroutine
end program

The above program produces the following output.

Solution: (5.00000, 3.00000)
Residual: (0.323E-11, 0.705E-11)
Iterations: 11
Function Evaluations: 15
Jacobian Evaluations: 1

Example 2

This example uses a least-squares approach to determine the coefficients of a polynomial that best fits a set of data.

program example
    use iso_fortran_env
    use nonlin_core
    use nonlin_least_squares, only : least_squares_solver
    implicit none

    ! Local Variables
    type(vecfcn_helper) :: obj
    procedure(vecfcn), pointer :: fcn
    type(least_squares_solver) :: solver
    real(real64) :: x(4), f(21) ! There are 4 coefficients and 21 data points

    ! Locate the routine containing the equations to solve
    fcn => fcns
    call obj%set_fcn(fcn, 21, 4)

    ! Define an initial guess
    x = 1.0d0 ! Equivalent to x = [1.0d0, 1.0d0, 1.0d0, 1.0d0]

    ! Solve
    call solver%solve(obj, x, f)

    ! Display the output
    print '(AF12.10)', "c0: ", x(4)
    print '(AF12.10)', "c1: ", x(3)
    print '(AF12.10)', "c2: ", x(2)
    print '(AF12.10)', "c3: ", x(1)
    print '(AF7.5)', "Max Residual: ", maxval(abs(f))

contains
    ! The function containing the data to fit
    subroutine fcns(x, f)
        ! Arguments
        real(real64), intent(in), dimension(:) :: x  ! Contains the coefficients
        real(real64), intent(out), dimension(:) :: f

        ! Local Variables
        real(real64), dimension(21) :: xp, yp

        ! Data to fit (21 data points)
        xp = [0.0d0, 0.1d0, 0.2d0, 0.3d0, 0.4d0, 0.5d0, 0.6d0, 0.7d0, 0.8d0, &
            0.9d0, 1.0d0, 1.1d0, 1.2d0, 1.3d0, 1.4d0, 1.5d0, 1.6d0, 1.7d0, &
            1.8d0, 1.9d0, 2.0d0]
        yp = [1.216737514d0, 1.250032542d0, 1.305579195d0, 1.040182335d0, &
            1.751867738d0, 1.109716707d0, 2.018141531d0, 1.992418729d0, &
            1.807916923d0, 2.078806005d0, 2.698801324d0, 2.644662712d0, &
            3.412756702d0, 4.406137221d0, 4.567156645d0, 4.999550779d0, &
            5.652854194d0, 6.784320119d0, 8.307936836d0, 8.395126494d0, &
            10.30252404d0]

        ! We'll apply a cubic polynomial model to this data:
        ! y = c3 * x**3 + c2 * x**2 + c1 * x + c0
        f = x(1) * xp**3 + x(2) * xp**2 + x(3) * xp + x(4) - yp

        ! For reference, the data was generated by adding random errors to
        ! the following polynomial: y = x**3 - 0.3 * x**2 + 1.2 * x + 0.3
    end subroutine
end program

The above program produces the following output.

c0: 1.1866142244
c1: 0.4466134462
c2: -.1223202909
c3: 1.0647627571
Max Residual: 0.50636

The following graph illustrates the fit.

Example 3

This example utilizes the polynomial type to fit a polynomial to the data set utilized in Example 2.

program example
    use iso_fortran_env
    use nonlin_polynomials
    implicit none

    ! Local Variables
    integer(int32) :: i
    real(real64), dimension(21) :: xp, yp, yf, yc, err
    real(real64) :: res
    type(polynomial) :: p

    ! Data to fit
    xp = [0.0d0, 0.1d0, 0.2d0, 0.3d0, 0.4d0, 0.5d0, 0.6d0, 0.7d0, 0.8d0, &
        0.9d0, 1.0d0, 1.1d0, 1.2d0, 1.3d0, 1.4d0, 1.5d0, 1.6d0, 1.7d0, &
        1.8d0, 1.9d0, 2.0d0]
    yp = [1.216737514d0, 1.250032542d0, 1.305579195d0, 1.040182335d0, &
        1.751867738d0, 1.109716707d0, 2.018141531d0, 1.992418729d0, &
        1.807916923d0, 2.078806005d0, 2.698801324d0, 2.644662712d0, &
        3.412756702d0, 4.406137221d0, 4.567156645d0, 4.999550779d0, &
        5.652854194d0, 6.784320119d0, 8.307936836d0, 8.395126494d0, &
        10.30252404d0]

    ! Create a copy of yp as it will be overwritten in the fit command
    yc = yp

    ! Fit the polynomial
    call p%fit(xp, yp, 3)

    ! Evaluate the polynomial at xp, and then determine the residual
    yf = p%evaluate(xp)
    err = abs(yf - yc)
    res = maxval(err)

    ! Print out the coefficients
    print '(AI0AF12.10)', ("c", i - 1, " = ", p%get(i), i = 1, 4)
    print '(AF7.5)', "Max Residual: ", res
end program

The above program yields the following coefficients.

c0 = 1.1866141861
c1 = 0.4466136311
c2 = -.1223204989
c3 = 1.0647628218
Max Residual: 0.50636

Notice, as expected, the results are very similar to the output of Example 2.

Example 4

This example uses the Nelder-Mead simplex method to find the minimum of the Rosenbrock function.

program example
    use iso_fortran_env
    use nonlin_optimize, only : nelder_mead
    use nonlin_core
    implicit none

    ! Local Variables
    type(nelder_mead) :: solver
    type(fcnnvar_helper) :: obj
    procedure(fcnnvar), pointer :: fcn
    real(real64) :: x(2), fout
    type(iteration_behavior) :: ib

    ! Initialization
    fcn => rosenbrock
    call obj%set_fcn(fcn, 2)

    ! Define an initial guess - the solution is (1, 1)
    call random_number(x)

    ! Call the solver
    call solver%solve(obj, x, fout, ib)

     ! Display the output
     print '(AF7.5AF7.5A)', "Minimum: (", x(1), ", ", x(2), ")"
     print '(AE9.3)', "Function Value: ", fout
     print '(AI0)', "Iterations: ", ib%iter_count
     print '(AI0)', "Function Evaluations: ", ib%fcn_count
contains
    ! Rosenbrock's Function
    function rosenbrock(x) result(f)
        real(real64), intent(in), dimension(:) :: x
        real(real64) :: f
        f = 1.0d2 * (x(2) - x(1)**2)**2 + (x(1) - 1.0d0)**2
    end function
end program

The above program produces the following output:

Minimum: (1.00000, 1.00000)
Function Value: 0.121E-12
Iterations: 52
Function Evaluations: 101

Notice, the convergence tolerance was set to its default value (1e-12).