@cindex solving nonlinear systems of equations @cindex nonlinear systems of equations, solution of @cindex systems of equations, nonlinear This chapter describes functions for multidimensional root-finding (solving nonlinear systems with @math{n} equations in @math{n} unknowns). The library provides low level components for a variety of iterative solvers and convergence tests. These can be combined by the user to achieve the desired solution, with full access to the intermediate steps of the iteration. Each class of methods uses the same framework, so that you can switch between solvers at runtime without needing to recompile your program. Each instance of a solver keeps track of its own state, allowing the solvers to be used in multi-threaded programs. The solvers are based on the original Fortran library @sc{minpack}. The header file @file{gsl_multiroots.h} contains prototypes for the multidimensional root finding functions and related declarations. @menu * Overview of Multidimensional Root Finding:: * Initializing the Multidimensional Solver:: * Providing the multidimensional system of equations to solve:: * Iteration of the multidimensional solver:: * Search Stopping Parameters for the multidimensional solver:: * Algorithms using Derivatives:: * Algorithms without Derivatives:: * Example programs for Multidimensional Root finding:: * References and Further Reading for Multidimensional Root Finding:: @end menu @node Overview of Multidimensional Root Finding @section Overview @cindex multidimensional root finding, overview The problem of multidimensional root finding requires the simultaneous solution of @math{n} equations, @math{f_i}, in @math{n} variables, @math{x_i}, @tex \beforedisplay $$ f_i (x_1, \dots, x_n) = 0 \qquad\hbox{for}~i = 1 \dots n. $$ \afterdisplay @end tex @ifinfo @example f_i (x_1, ..., x_n) = 0 for i = 1 ... n. @end example @end ifinfo @noindent In general there are no bracketing methods available for @math{n} dimensional systems, and no way of knowing whether any solutions exist. All algorithms proceed from an initial guess using a variant of the Newton iteration, @tex \beforedisplay $$ x \to x' = x - J^{-1} f(x) $$ \afterdisplay @end tex @ifinfo @example x -> x' = x - J^@{-1@} f(x) @end example @end ifinfo @noindent where @math{x}, @math{f} are vector quantities and @math{J} is the Jacobian matrix @c{$J_{ij} = \partial f_i / \partial x_j$} @math{J_@{ij@} = d f_i / d x_j}. Additional strategies can be used to enlarge the region of convergence. These include requiring a decrease in the norm @math{|f|} on each step proposed by Newton's method, or taking steepest-descent steps in the direction of the negative gradient of @math{|f|}. Several root-finding algorithms are available within a single framework. The user provides a high-level driver for the algorithms, and the library provides the individual functions necessary for each of the steps. There are three main phases of the iteration. The steps are, @itemize @bullet @item initialize solver state, @var{s}, for algorithm @var{T} @item update @var{s} using the iteration @var{T} @item test @var{s} for convergence, and repeat iteration if necessary @end itemize @noindent The evaluation of the Jacobian matrix can be problematic, either because programming the derivatives is intractable or because computation of the @math{n^2} terms of the matrix becomes too expensive. For these reasons the algorithms provided by the library are divided into two classes according to whether the derivatives are available or not. The state for solvers with an analytic Jacobian matrix is held in a @code{gsl_multiroot_fdfsolver} struct. The updating procedure requires both the function and its derivatives to be supplied by the user. The state for solvers which do not use an analytic Jacobian matrix is held in a @code{gsl_multiroot_fsolver} struct. The updating procedure uses only function evaluations (not derivatives). The algorithms estimate the matrix @math{J} or @c{$J^{-1}$} @math{J^@{-1@}} by approximate methods. @node Initializing the Multidimensional Solver @section Initializing the Solver The following functions initialize a multidimensional solver, either with or without derivatives. The solver itself depends only on the dimension of the problem and the algorithm and can be reused for different problems. @deftypefun {gsl_multiroot_fsolver *} gsl_multiroot_fsolver_alloc (const gsl_multiroot_fsolver_type * @var{T}, size_t @var{n}) This function returns a pointer to a newly allocated instance of a solver of type @var{T} for a system of @var{n} dimensions. For example, the following code creates an instance of a hybrid solver, to solve a 3-dimensional system of equations. @example const gsl_multiroot_fsolver_type * T = gsl_multiroot_fsolver_hybrid; gsl_multiroot_fsolver * s = gsl_multiroot_fsolver_alloc (T, 3); @end example @noindent If there is insufficient memory to create the solver then the function returns a null pointer and the error handler is invoked with an error code of @code{GSL_ENOMEM}. @end deftypefun @deftypefun {gsl_multiroot_fdfsolver *} gsl_multiroot_fdfsolver_alloc (const gsl_multiroot_fdfsolver_type * @var{T}, size_t @var{n}) This function returns a pointer to a newly allocated instance of a derivative solver of type @var{T} for a system of @var{n} dimensions. For example, the following code creates an instance of a Newton-Raphson solver, for a 2-dimensional system of equations. @example const gsl_multiroot_fdfsolver_type * T = gsl_multiroot_fdfsolver_newton; gsl_multiroot_fdfsolver * s = gsl_multiroot_fdfsolver_alloc (T, 2); @end example @noindent If there is insufficient memory to create the solver then the function returns a null pointer and the error handler is invoked with an error code of @code{GSL_ENOMEM}. @end deftypefun @deftypefun int gsl_multiroot_fsolver_set (gsl_multiroot_fsolver * @var{s}, gsl_multiroot_function * @var{f}, gsl_vector * @var{x}) This function sets, or resets, an existing solver @var{s} to use the function @var{f} and the initial guess @var{x}. @end deftypefun @deftypefun int gsl_multiroot_fdfsolver_set (gsl_multiroot_fdfsolver * @var{s}, gsl_multiroot_function_fdf * @var{fdf}, gsl_vector * @var{x}) This function sets, or resets, an existing solver @var{s} to use the function and derivative @var{fdf} and the initial guess @var{x}. @end deftypefun @deftypefun void gsl_multiroot_fsolver_free (gsl_multiroot_fsolver * @var{s}) @deftypefunx void gsl_multiroot_fdfsolver_free (gsl_multiroot_fdfsolver * @var{s}) These functions free all the memory associated with the solver @var{s}. @end deftypefun @deftypefun {const char *} gsl_multiroot_fsolver_name (const gsl_multiroot_fsolver * @var{s}) @deftypefunx {const char *} gsl_multiroot_fdfsolver_name (const gsl_multiroot_fdfsolver * @var{s}) These functions return a pointer to the name of the solver. For example, @example printf ("s is a '%s' solver\n", gsl_multiroot_fdfsolver_name (s)); @end example @noindent would print something like @code{s is a 'newton' solver}. @end deftypefun @node Providing the multidimensional system of equations to solve @section Providing the function to solve @cindex multidimensional root finding, providing a function to solve You must provide @math{n} functions of @math{n} variables for the root finders to operate on. In order to allow for general parameters the functions are defined by the following data types: @deftp {Data Type} gsl_multiroot_function This data type defines a general system of functions with parameters. @table @code @item int (* f) (const gsl_vector * @var{x}, void * @var{params}, gsl_vector * @var{f}) this function should store the vector result @c{$f(x,\hbox{\it params})$} @math{f(x,params)} in @var{f} for argument @var{x} and parameters @var{params}, returning an appropriate error code if the function cannot be computed. @item size_t n the dimension of the system, i.e. the number of components of the vectors @var{x} and @var{f}. @item void * params a pointer to the parameters of the function. @end table @end deftp @noindent Here is an example using Powell's test function, @tex \beforedisplay $$ f_1(x) = A x_0 x_1 - 1, f_2(x) = \exp(-x_0) + \exp(-x_1) - (1 + 1/A) $$ \afterdisplay @end tex @ifinfo @example f_1(x) = A x_0 x_1 - 1, f_2(x) = exp(-x_0) + exp(-x_1) - (1 + 1/A) @end example @end ifinfo @noindent with @math{A = 10^4}. The following code defines a @code{gsl_multiroot_function} system @code{F} which you could pass to a solver: @example struct powell_params @{ double A; @}; int powell (gsl_vector * x, void * p, gsl_vector * f) @{ struct powell_params * params = *(struct powell_params *)p; const double A = (params->A); const double x0 = gsl_vector_get(x,0); const double x1 = gsl_vector_get(x,1); gsl_vector_set (f, 0, A * x0 * x1 - 1); gsl_vector_set (f, 1, (exp(-x0) + exp(-x1) - (1.0 + 1.0/A))); return GSL_SUCCESS @} gsl_multiroot_function F; struct powell_params params = @{ 10000.0 @}; F.f = &powell; F.n = 2; F.params = ¶ms; @end example @deftp {Data Type} gsl_multiroot_function_fdf This data type defines a general system of functions with parameters and the corresponding Jacobian matrix of derivatives, @table @code @item int (* f) (const gsl_vector * @var{x}, void * @var{params}, gsl_vector * @var{f}) this function should store the vector result @c{$f(x,\hbox{\it params})$} @math{f(x,params)} in @var{f} for argument @var{x} and parameters @var{params}, returning an appropriate error code if the function cannot be computed. @item int (* df) (const gsl_vector * @var{x}, void * @var{params}, gsl_matrix * @var{J}) this function should store the @var{n}-by-@var{n} matrix result @c{$J_{ij} = \partial f_i(x,\hbox{\it params}) / \partial x_j$} @math{J_ij = d f_i(x,params) / d x_j} in @var{J} for argument @var{x} and parameters @var{params}, returning an appropriate error code if the function cannot be computed. @item int (* fdf) (const gsl_vector * @var{x}, void * @var{params}, gsl_vector * @var{f}, gsl_matrix * @var{J}) This function should set the values of the @var{f} and @var{J} as above, for arguments @var{x} and parameters @var{params}. This function provides an optimization of the separate functions for @math{f(x)} and @math{J(x)}---it is always faster to compute the function and its derivative at the same time. @item size_t n the dimension of the system, i.e. the number of components of the vectors @var{x} and @var{f}. @item void * params a pointer to the parameters of the function. @end table @end deftp @noindent The example of Powell's test function defined above can be extended to include analytic derivatives using the following code, @example int powell_df (gsl_vector * x, void * p, gsl_matrix * J) @{ struct powell_params * params = *(struct powell_params *)p; const double A = (params->A); const double x0 = gsl_vector_get(x,0); const double x1 = gsl_vector_get(x,1); gsl_matrix_set (J, 0, 0, A * x1); gsl_matrix_set (J, 0, 1, A * x0); gsl_matrix_set (J, 1, 0, -exp(-x0)); gsl_matrix_set (J, 1, 1, -exp(-x1)); return GSL_SUCCESS @} int powell_fdf (gsl_vector * x, void * p, gsl_matrix * f, gsl_matrix * J) @{ struct powell_params * params = *(struct powell_params *)p; const double A = (params->A); const double x0 = gsl_vector_get(x,0); const double x1 = gsl_vector_get(x,1); const double u0 = exp(-x0); const double u1 = exp(-x1); gsl_vector_set (f, 0, A * x0 * x1 - 1); gsl_vector_set (f, 1, u0 + u1 - (1 + 1/A)); gsl_matrix_set (J, 0, 0, A * x1); gsl_matrix_set (J, 0, 1, A * x0); gsl_matrix_set (J, 1, 0, -u0); gsl_matrix_set (J, 1, 1, -u1); return GSL_SUCCESS @} gsl_multiroot_function_fdf FDF; FDF.f = &powell_f; FDF.df = &powell_df; FDF.fdf = &powell_fdf; FDF.n = 2; FDF.params = 0; @end example @noindent Note that the function @code{powell_fdf} is able to reuse existing terms from the function when calculating the Jacobian, thus saving time. @node Iteration of the multidimensional solver @section Iteration The following functions drive the iteration of each algorithm. Each function performs one iteration to update the state of any solver of the corresponding type. The same functions work for all solvers so that different methods can be substituted at runtime without modifications to the code. @deftypefun int gsl_multiroot_fsolver_iterate (gsl_multiroot_fsolver * @var{s}) @deftypefunx int gsl_multiroot_fdfsolver_iterate (gsl_multiroot_fdfsolver * @var{s}) These functions perform a single iteration of the solver @var{s}. If the iteration encounters an unexpected problem then an error code will be returned, @table @code @item GSL_EBADFUNC the iteration encountered a singular point where the function or its derivative evaluated to @code{Inf} or @code{NaN}. @item GSL_ENOPROG the iteration is not making any progress, preventing the algorithm from continuing. @end table @end deftypefun The solver maintains a current best estimate of the root at all times. This information can be accessed with the following auxiliary functions, @deftypefun {gsl_vector *} gsl_multiroot_fsolver_root (const gsl_multiroot_fsolver * @var{s}) @deftypefunx {gsl_vector *} gsl_multiroot_fdfsolver_root (const gsl_multiroot_fdfsolver * @var{s}) These functions return the current estimate of the root for the solver @var{s}. @end deftypefun @deftypefun {gsl_vector *} gsl_multiroot_fsolver_f (const gsl_multiroot_fsolver * @var{s}) @deftypefunx {gsl_vector *} gsl_multiroot_fdfsolver_f (const gsl_multiroot_fdfsolver * @var{s}) These functions return the function value @math{f(x)} at the current estimate of the root for the solver @var{s}. @end deftypefun @deftypefun {gsl_vector *} gsl_multiroot_fsolver_dx (const gsl_multiroot_fsolver * @var{s}) @deftypefunx {gsl_vector *} gsl_multiroot_fdfsolver_dx (const gsl_multiroot_fdfsolver * @var{s}) These functions return the last step @math{dx} taken by the solver @var{s}. @end deftypefun @node Search Stopping Parameters for the multidimensional solver @section Search Stopping Parameters @cindex root finding, stopping parameters A root finding procedure should stop when one of the following conditions is true: @itemize @bullet @item A multidimensional root has been found to within the user-specified precision. @item A user-specified maximum number of iterations has been reached. @item An error has occurred. @end itemize @noindent The handling of these conditions is under user control. The functions below allow the user to test the precision of the current result in several standard ways. @deftypefun int gsl_multiroot_test_delta (const gsl_vector * @var{dx}, const gsl_vector * @var{x}, double @var{epsabs}, double @var{epsrel}) This function tests for the convergence of the sequence by comparing the last step @var{dx} with the absolute error @var{epsabs} and relative error @var{epsrel} to the current position @var{x}. The test returns @code{GSL_SUCCESS} if the following condition is achieved, @tex \beforedisplay $$ |dx_i| < \hbox{\it epsabs} + \hbox{\it epsrel\/}\, |x_i| $$ \afterdisplay @end tex @ifinfo @example |dx_i| < epsabs + epsrel |x_i| @end example @end ifinfo @noindent for each component of @var{x} and returns @code{GSL_CONTINUE} otherwise. @end deftypefun @cindex residual, in nonlinear systems of equations @deftypefun int gsl_multiroot_test_residual (const gsl_vector * @var{f}, double @var{epsabs}) This function tests the residual value @var{f} against the absolute error bound @var{epsabs}. The test returns @code{GSL_SUCCESS} if the following condition is achieved, @tex \beforedisplay $$ \sum_i |f_i| < \hbox{\it epsabs} $$ \afterdisplay @end tex @ifinfo @example \sum_i |f_i| < epsabs @end example @end ifinfo @noindent and returns @code{GSL_CONTINUE} otherwise. This criterion is suitable for situations where the precise location of the root, @math{x}, is unimportant provided a value can be found where the residual is small enough. @end deftypefun @comment ============================================================ @node Algorithms using Derivatives @section Algorithms using Derivatives The root finding algorithms described in this section make use of both the function and its derivative. They require an initial guess for the location of the root, but there is no absolute guarantee of convergence---the function must be suitable for this technique and the initial guess must be sufficiently close to the root for it to work. When the conditions are satisfied then convergence is quadratic. @comment ============================================================ @cindex HYBRID algorithms for nonlinear systems @deffn {Derivative Solver} gsl_multiroot_fdfsolver_hybridsj @cindex HYBRIDSJ algorithm @cindex MINPACK, minimization algorithms This is a modified version of Powell's Hybrid method as implemented in the @sc{hybrj} algorithm in @sc{minpack}. Minpack was written by Jorge J. Mor@'e, Burton S. Garbow and Kenneth E. Hillstrom. The Hybrid algorithm retains the fast convergence of Newton's method but will also reduce the residual when Newton's method is unreliable. The algorithm uses a generalized trust region to keep each step under control. In order to be accepted a proposed new position @math{x'} must satisfy the condition @math{|D (x' - x)| < \delta}, where @math{D} is a diagonal scaling matrix and @math{\delta} is the size of the trust region. The components of @math{D} are computed internally, using the column norms of the Jacobian to estimate the sensitivity of the residual to each component of @math{x}. This improves the behavior of the algorithm for badly scaled functions. On each iteration the algorithm first determines the standard Newton step by solving the system @math{J dx = - f}. If this step falls inside the trust region it is used as a trial step in the next stage. If not, the algorithm uses the linear combination of the Newton and gradient directions which is predicted to minimize the norm of the function while staying inside the trust region, @tex \beforedisplay $$ dx = - \alpha J^{-1} f(x) - \beta \nabla |f(x)|^2. $$ \afterdisplay @end tex @ifinfo @example dx = - \alpha J^@{-1@} f(x) - \beta \nabla |f(x)|^2. @end example @end ifinfo @noindent This combination of Newton and gradient directions is referred to as a @dfn{dogleg step}. The proposed step is now tested by evaluating the function at the resulting point, @math{x'}. If the step reduces the norm of the function sufficiently then it is accepted and size of the trust region is increased. If the proposed step fails to improve the solution then the size of the trust region is decreased and another trial step is computed. The speed of the algorithm is increased by computing the changes to the Jacobian approximately, using a rank-1 update. If two successive attempts fail to reduce the residual then the full Jacobian is recomputed. The algorithm also monitors the progress of the solution and returns an error if several steps fail to make any improvement, @table @code @item GSL_ENOPROG the iteration is not making any progress, preventing the algorithm from continuing. @item GSL_ENOPROGJ re-evaluations of the Jacobian indicate that the iteration is not making any progress, preventing the algorithm from continuing. @end table @end deffn @deffn {Derivative Solver} gsl_multiroot_fdfsolver_hybridj @cindex HYBRIDJ algorithm This algorithm is an unscaled version of @code{hybridsj}. The steps are controlled by a spherical trust region @math{|x' - x| < \delta}, instead of a generalized region. This can be useful if the generalized region estimated by @code{hybridsj} is inappropriate. @end deffn @deffn {Derivative Solver} gsl_multiroot_fdfsolver_newton @cindex Newton's method for systems of nonlinear equations Newton's Method is the standard root-polishing algorithm. The algorithm begins with an initial guess for the location of the solution. On each iteration a linear approximation to the function @math{F} is used to estimate the step which will zero all the components of the residual. The iteration is defined by the following sequence, @tex \beforedisplay $$ x \to x' = x - J^{-1} f(x) $$ \afterdisplay @end tex @ifinfo @example x -> x' = x - J^@{-1@} f(x) @end example @end ifinfo @noindent where the Jacobian matrix @math{J} is computed from the derivative functions provided by @var{f}. The step @math{dx} is obtained by solving the linear system, @tex \beforedisplay $$ J \,dx = - f(x) $$ \afterdisplay @end tex @ifinfo @example J dx = - f(x) @end example @end ifinfo @noindent using LU decomposition. @end deffn @comment ============================================================ @deffn {Derivative Solver} gsl_multiroot_fdfsolver_gnewton @cindex Modified Newton's method for nonlinear systems @cindex Newton algorithm, globally convergent This is a modified version of Newton's method which attempts to improve global convergence by requiring every step to reduce the Euclidean norm of the residual, @math{|f(x)|}. If the Newton step leads to an increase in the norm then a reduced step of relative size, @tex \beforedisplay $$ t = (\sqrt{1 + 6 r} - 1) / (3 r) $$ \afterdisplay @end tex @ifinfo @example t = (\sqrt(1 + 6 r) - 1) / (3 r) @end example @end ifinfo @noindent is proposed, with @math{r} being the ratio of norms @math{|f(x')|^2/|f(x)|^2}. This procedure is repeated until a suitable step size is found. @end deffn @comment ============================================================ @node Algorithms without Derivatives @section Algorithms without Derivatives The algorithms described in this section do not require any derivative information to be supplied by the user. Any derivatives needed are approximated by finite differences. Note that if the finite-differencing step size chosen by these routines is inappropriate, an explicit user-supplied numerical derivative can always be used with the algorithms described in the previous section. @deffn {Solver} gsl_multiroot_fsolver_hybrids @cindex HYBRIDS algorithm, scaled without derivatives This is a version of the Hybrid algorithm which replaces calls to the Jacobian function by its finite difference approximation. The finite difference approximation is computed using @code{gsl_multiroots_fdjac} with a relative step size of @code{GSL_SQRT_DBL_EPSILON}. Note that this step size will not be suitable for all problems. @end deffn @deffn {Solver} gsl_multiroot_fsolver_hybrid @cindex HYBRID algorithm, unscaled without derivatives This is a finite difference version of the Hybrid algorithm without internal scaling. @end deffn @comment ============================================================ @deffn {Solver} gsl_multiroot_fsolver_dnewton @cindex Discrete Newton algorithm for multidimensional roots @cindex Newton algorithm, discrete The @dfn{discrete Newton algorithm} is the simplest method of solving a multidimensional system. It uses the Newton iteration @tex \beforedisplay $$ x \to x - J^{-1} f(x) $$ \afterdisplay @end tex @ifinfo @example x -> x - J^@{-1@} f(x) @end example @end ifinfo @noindent where the Jacobian matrix @math{J} is approximated by taking finite differences of the function @var{f}. The approximation scheme used by this implementation is, @tex \beforedisplay $$ J_{ij} = (f_i(x + \delta_j) - f_i(x)) / \delta_j $$ \afterdisplay @end tex @ifinfo @example J_@{ij@} = (f_i(x + \delta_j) - f_i(x)) / \delta_j @end example @end ifinfo @noindent where @math{\delta_j} is a step of size @math{\sqrt\epsilon |x_j|} with @math{\epsilon} being the machine precision (@c{$\epsilon \approx 2.22 \times 10^{-16}$} @math{\epsilon \approx 2.22 \times 10^-16}). The order of convergence of Newton's algorithm is quadratic, but the finite differences require @math{n^2} function evaluations on each iteration. The algorithm may become unstable if the finite differences are not a good approximation to the true derivatives. @end deffn @comment ============================================================ @deffn {Solver} gsl_multiroot_fsolver_broyden @cindex Broyden algorithm for multidimensional roots @cindex multidimensional root finding, Broyden algorithm The @dfn{Broyden algorithm} is a version of the discrete Newton algorithm which attempts to avoids the expensive update of the Jacobian matrix on each iteration. The changes to the Jacobian are also approximated, using a rank-1 update, @tex \beforedisplay $$ J^{-1} \to J^{-1} - (J^{-1} df - dx) dx^T J^{-1} / dx^T J^{-1} df $$ \afterdisplay @end tex @ifinfo @example J^@{-1@} \to J^@{-1@} - (J^@{-1@} df - dx) dx^T J^@{-1@} / dx^T J^@{-1@} df @end example @end ifinfo @noindent where the vectors @math{dx} and @math{df} are the changes in @math{x} and @math{f}. On the first iteration the inverse Jacobian is estimated using finite differences, as in the discrete Newton algorithm. This approximation gives a fast update but is unreliable if the changes are not small, and the estimate of the inverse Jacobian becomes worse as time passes. The algorithm has a tendency to become unstable unless it starts close to the root. The Jacobian is refreshed if this instability is detected (consult the source for details). This algorithm is included only for demonstration purposes, and is not recommended for serious use. @end deffn @comment ============================================================ @node Example programs for Multidimensional Root finding @section Examples The multidimensional solvers are used in a similar way to the one-dimensional root finding algorithms. This first example demonstrates the @code{hybrids} scaled-hybrid algorithm, which does not require derivatives. The program solves the Rosenbrock system of equations, @tex \beforedisplay $$ f_1 (x, y) = a (1 - x),~ f_2 (x, y) = b (y - x^2) $$ \afterdisplay @end tex @ifinfo @example f_1 (x, y) = a (1 - x) f_2 (x, y) = b (y - x^2) @end example @end ifinfo @noindent with @math{a = 1, b = 10}. The solution of this system lies at @math{(x,y) = (1,1)} in a narrow valley. The first stage of the program is to define the system of equations, @example #include #include #include #include struct rparams @{ double a; double b; @}; int rosenbrock_f (const gsl_vector * x, void *params, gsl_vector * f) @{ double a = ((struct rparams *) params)->a; double b = ((struct rparams *) params)->b; const double x0 = gsl_vector_get (x, 0); const double x1 = gsl_vector_get (x, 1); const double y0 = a * (1 - x0); const double y1 = b * (x1 - x0 * x0); gsl_vector_set (f, 0, y0); gsl_vector_set (f, 1, y1); return GSL_SUCCESS; @} @end example @noindent The main program begins by creating the function object @code{f}, with the arguments @code{(x,y)} and parameters @code{(a,b)}. The solver @code{s} is initialized to use this function, with the @code{hybrids} method. @example int main (void) @{ const gsl_multiroot_fsolver_type *T; gsl_multiroot_fsolver *s; int status; size_t i, iter = 0; const size_t n = 2; struct rparams p = @{1.0, 10.0@}; gsl_multiroot_function f = @{&rosenbrock_f, n, &p@}; double x_init[2] = @{-10.0, -5.0@}; gsl_vector *x = gsl_vector_alloc (n); gsl_vector_set (x, 0, x_init[0]); gsl_vector_set (x, 1, x_init[1]); T = gsl_multiroot_fsolver_hybrids; s = gsl_multiroot_fsolver_alloc (T, 2); gsl_multiroot_fsolver_set (s, &f, x); print_state (iter, s); do @{ iter++; status = gsl_multiroot_fsolver_iterate (s); print_state (iter, s); if (status) /* check if solver is stuck */ break; status = gsl_multiroot_test_residual (s->f, 1e-7); @} while (status == GSL_CONTINUE && iter < 1000); printf ("status = %s\n", gsl_strerror (status)); gsl_multiroot_fsolver_free (s); gsl_vector_free (x); return 0; @} @end example @noindent Note that it is important to check the return status of each solver step, in case the algorithm becomes stuck. If an error condition is detected, indicating that the algorithm cannot proceed, then the error can be reported to the user, a new starting point chosen or a different algorithm used. The intermediate state of the solution is displayed by the following function. The solver state contains the vector @code{s->x} which is the current position, and the vector @code{s->f} with corresponding function values. @example int print_state (size_t iter, gsl_multiroot_fsolver * s) @{ printf ("iter = %3u x = % .3f % .3f " "f(x) = % .3e % .3e\n", iter, gsl_vector_get (s->x, 0), gsl_vector_get (s->x, 1), gsl_vector_get (s->f, 0), gsl_vector_get (s->f, 1)); @} @end example @noindent Here are the results of running the program. The algorithm is started at @math{(-10,-5)} far from the solution. Since the solution is hidden in a narrow valley the earliest steps follow the gradient of the function downhill, in an attempt to reduce the large value of the residual. Once the root has been approximately located, on iteration 8, the Newton behavior takes over and convergence is very rapid. @smallexample iter = 0 x = -10.000 -5.000 f(x) = 1.100e+01 -1.050e+03 iter = 1 x = -10.000 -5.000 f(x) = 1.100e+01 -1.050e+03 iter = 2 x = -3.976 24.827 f(x) = 4.976e+00 9.020e+01 iter = 3 x = -3.976 24.827 f(x) = 4.976e+00 9.020e+01 iter = 4 x = -3.976 24.827 f(x) = 4.976e+00 9.020e+01 iter = 5 x = -1.274 -5.680 f(x) = 2.274e+00 -7.302e+01 iter = 6 x = -1.274 -5.680 f(x) = 2.274e+00 -7.302e+01 iter = 7 x = 0.249 0.298 f(x) = 7.511e-01 2.359e+00 iter = 8 x = 0.249 0.298 f(x) = 7.511e-01 2.359e+00 iter = 9 x = 1.000 0.878 f(x) = 1.268e-10 -1.218e+00 iter = 10 x = 1.000 0.989 f(x) = 1.124e-11 -1.080e-01 iter = 11 x = 1.000 1.000 f(x) = 0.000e+00 0.000e+00 status = success @end smallexample @noindent Note that the algorithm does not update the location on every iteration. Some iterations are used to adjust the trust-region parameter, after trying a step which was found to be divergent, or to recompute the Jacobian, when poor convergence behavior is detected. The next example program adds derivative information, in order to accelerate the solution. There are two derivative functions @code{rosenbrock_df} and @code{rosenbrock_fdf}. The latter computes both the function and its derivative simultaneously. This allows the optimization of any common terms. For simplicity we substitute calls to the separate @code{f} and @code{df} functions at this point in the code below. @example int rosenbrock_df (const gsl_vector * x, void *params, gsl_matrix * J) @{ const double a = ((struct rparams *) params)->a; const double b = ((struct rparams *) params)->b; const double x0 = gsl_vector_get (x, 0); const double df00 = -a; const double df01 = 0; const double df10 = -2 * b * x0; const double df11 = b; gsl_matrix_set (J, 0, 0, df00); gsl_matrix_set (J, 0, 1, df01); gsl_matrix_set (J, 1, 0, df10); gsl_matrix_set (J, 1, 1, df11); return GSL_SUCCESS; @} int rosenbrock_fdf (const gsl_vector * x, void *params, gsl_vector * f, gsl_matrix * J) @{ rosenbrock_f (x, params, f); rosenbrock_df (x, params, J); return GSL_SUCCESS; @} @end example @noindent The main program now makes calls to the corresponding @code{fdfsolver} versions of the functions, @example int main (void) @{ const gsl_multiroot_fdfsolver_type *T; gsl_multiroot_fdfsolver *s; int status; size_t i, iter = 0; const size_t n = 2; struct rparams p = @{1.0, 10.0@}; gsl_multiroot_function_fdf f = @{&rosenbrock_f, &rosenbrock_df, &rosenbrock_fdf, n, &p@}; double x_init[2] = @{-10.0, -5.0@}; gsl_vector *x = gsl_vector_alloc (n); gsl_vector_set (x, 0, x_init[0]); gsl_vector_set (x, 1, x_init[1]); T = gsl_multiroot_fdfsolver_gnewton; s = gsl_multiroot_fdfsolver_alloc (T, n); gsl_multiroot_fdfsolver_set (s, &f, x); print_state (iter, s); do @{ iter++; status = gsl_multiroot_fdfsolver_iterate (s); print_state (iter, s); if (status) break; status = gsl_multiroot_test_residual (s->f, 1e-7); @} while (status == GSL_CONTINUE && iter < 1000); printf ("status = %s\n", gsl_strerror (status)); gsl_multiroot_fdfsolver_free (s); gsl_vector_free (x); return 0; @} @end example @noindent The addition of derivative information to the @code{hybrids} solver does not make any significant difference to its behavior, since it able to approximate the Jacobian numerically with sufficient accuracy. To illustrate the behavior of a different derivative solver we switch to @code{gnewton}. This is a traditional Newton solver with the constraint that it scales back its step if the full step would lead ``uphill''. Here is the output for the @code{gnewton} algorithm, @smallexample iter = 0 x = -10.000 -5.000 f(x) = 1.100e+01 -1.050e+03 iter = 1 x = -4.231 -65.317 f(x) = 5.231e+00 -8.321e+02 iter = 2 x = 1.000 -26.358 f(x) = -8.882e-16 -2.736e+02 iter = 3 x = 1.000 1.000 f(x) = -2.220e-16 -4.441e-15 status = success @end smallexample @noindent The convergence is much more rapid, but takes a wide excursion out to the point @math{(-4.23,-65.3)}. This could cause the algorithm to go astray in a realistic application. The hybrid algorithm follows the downhill path to the solution more reliably. @node References and Further Reading for Multidimensional Root Finding @section References and Further Reading The original version of the Hybrid method is described in the following articles by Powell, @itemize @asis @item M.J.D. Powell, ``A Hybrid Method for Nonlinear Equations'' (Chap 6, p 87--114) and ``A Fortran Subroutine for Solving systems of Nonlinear Algebraic Equations'' (Chap 7, p 115--161), in @cite{Numerical Methods for Nonlinear Algebraic Equations}, P. Rabinowitz, editor. Gordon and Breach, 1970. @end itemize @noindent The following papers are also relevant to the algorithms described in this section, @itemize @asis @item J.J. Mor@'e, M.Y. Cosnard, ``Numerical Solution of Nonlinear Equations'', @cite{ACM Transactions on Mathematical Software}, Vol 5, No 1, (1979), p 64--85 @item C.G. Broyden, ``A Class of Methods for Solving Nonlinear Simultaneous Equations'', @cite{Mathematics of Computation}, Vol 19 (1965), p 577--593 @item J.J. Mor@'e, B.S. Garbow, K.E. Hillstrom, ``Testing Unconstrained Optimization Software'', ACM Transactions on Mathematical Software, Vol 7, No 1 (1981), p 17--41 @end itemize