=begin = Ordinary Differential Equations == Classes for ODE solver --- GSL::Odeiv::System --- GSL::Odeiv::Step --- GSL::Odeiv::Control --- GSL::Odeiv::Evolve These are GSL structure wrappers. --- GSL::Odeiv::Solver Another higher-level interface to ODE system classes. == Class Description === GSL::Odeiv::Step The lowest level components are the stepping functions which advance a solution from time ((|t|)) to ((|t+h|)) for a fixed step-size ((|h|)) and estimate the resulting local error. --- GSL::Odeiv::Step.alloc(T, dim) Constructor for a stepping function of an algorithm type ((|T|)) for a system of dimension ((|dim|)). The algorithms are specified by one of the constants under the (({GSL::Odeiv::Step})) class, as (1) (({GSL::Odeiv::Step::RK2})), Embedded 2nd order Runge-Kutta with 3rd order error estimate. (2) (({GSL::Odeiv::Step::RK4})), 4th order (classical) Runge-Kutta. (3) (({GSL::Odeiv::Step::RKF45})), Embedded 4th order Runge-Kutta-Fehlberg method with 5th order error estimate. This method is a good general-purpose integrator. (4) (({GSL::Odeiv::Step::RKCK})), Embedded 4th order Runge-Kutta Cash-Karp method with 5th order error estimate. (5) (({GSL::Odeiv::Step::RK8PD})), Embedded 8th order Runge-Kutta Prince-Dormand method with 9th order error estimate. (6) (({GSL::Odeiv::Step::RK2IMP})), Implicit 2nd order Runge-Kutta at Gaussian points (7) (({GSL::Odeiv::Step::RK4IMP})), Implicit 4th order Runge-Kutta at Gaussian points (8) (({GSL::Odeiv::Step::BSIMP})), Implicit Bulirsch-Stoer method of Bader and Deuflhard. This algorithm requires the Jacobian. (9) (({GSL::Odeiv::Step::GEAR1})), M=1 implicit Gear method (10) (({GSL::Odeiv::Step::GEAR2})), M=2 implicit Gear method (11) (({GSL::Odeiv::Step::RK2SIMP})) (GSL-1.6) * Ex: step = Odeiv::Step.alloc(Odeiv::Step::RKF45, 2) The algorithm types can also be given by a String, same as the C struct name, (1) "(({rk2}))" or "(({gsl_odeiv_step_rk2}))" (2) "(({rk4}))" or "(({gsl_odeiv_step_rk4}))" (3) "(({rkf45}))" or "(({gsl_odeiv_step_rkf45}))" (4) "(({rkck}))" or "(({gsl_odeiv_step_rkck}))" (5) "(({rk8pd}))" or "(({gsl_odeiv_step_rk8pd}))" (6) "(({rk2imp}))" or "(({gsl_odeiv_step_rk2imp}))" (7) "(({rk4imp}))" or "(({gsl_odeiv_step_rk4imp}))" (8) "(({bsimp}))" or "(({gsl_odeiv_step_bsimp}))" (9) "(({gear1}))" or "(({gsl_odeiv_step_gear1}))" (10) "(({gear2}))" or "(({gsl_odeiv_step_gear2}))" (10) "(({rk2simp}))" or "(({gsl_odeiv_step_rk2simp}))" (GSL-1.6) * Ex: step = Odeiv::Step.alloc("bsimp", 4) step2 = Odeiv::Step.alloc("gsl_odeiv_step_rkck", 3) --- GSL::Odeiv::Step#reset This method resets the stepper. It should be used whenever the next use of s will not be a continuation of a previous step. --- GSL::Odeiv::Step#name Returns the name of the stepper as a String. For example, require("gsl") include Odeiv s = Step.alloc(Step::RK4, 2) printf("step method is '%s'\n", s.name) would print something like step method is 'rk4'. --- GSL::Odeiv::Step#order Returns the order of the stepper on the previous step. This order can vary if the stepper itself is adaptive. --- GSL::Odeiv::Step#apply(t, h, y, yerr, dydt_in, dydt_out, sys) --- GSL::Odeiv::Step#apply(t, h, y, yerr, dydt_in, sys) --- GSL::Odeiv::Step#apply(t, h, y, yerr, sys) This method applies the stepper to the system of equations defined by ((|dydt|)), using the step size ((|h|)) to advance the system from time ((|t|)) and state ((|y|)) to time ((|t+h|)). The new state of the system is stored in ((|y|)) on output, with an estimate of the absolute error in each component stored in ((|yerr|)). If the argument ((|dydt_in|)) is not (({nil})) it should be a (()) object containing the derivatives for the system at time ((|t|)) on input. This is optional as the derivatives will be computed internally if they are not provided, but allows the reuse of existing derivative information. On output the new derivatives of the system at time ((|t+h|)) will be stored in ((|dydt_out|)) if it is not nil. === GSL::Odeiv::System --- GSL::Odeiv::System.alloc(func, jac, dim) --- GSL::Odeiv::System.alloc(func, dim) Constructor. This defines a general ODE system with the dimension ((|dim|)). * Ex: # t: variable (scalar) # y: vector # dydt: vector # params: scalar or an array func = Proc.new { |t, y, dydt, params| mu = params dydt[0] = y[1] dydt[1] = -y[0] - mu*y[1]*(y[0]*y[0] - 1.0) } The third argument ((|jac|)) is also a Proc objects, to calculate jacobian. * Ex: # t: scalar # y: vector # dfdy: matrix, jacobian # dfdt: vector # params: scalar of an array jac = Proc.new { |t, y, dfdy, dfdt, params| mu = params dfdy.set(0, 0, 0.0) dfdy.set(0, 1, 1.0) dfdy.set(1, 0, -2*mu*y[0]*y[1] - 1.0) dfdy.set(1, 1, -mu*(y[0]*y[0] - 1.0)) dfdt[0] = 0.0 dfdt[1] = 0.0 } Note that some of the simpler solver algorithms do not make use of the Jacobian matrix, so it is not always strictly necessary to provide it. Thus the constructor is called as sys = GSL:Odeiv::System.alloc(func, jac, dim) # for "BSIMP" algorithm sys = GSL:Odeiv::System.alloc(func, nil, dim) # for others, replaced by nil sys = GSL:Odeiv::System.alloc(func, dim) # or omit --- GSL::Odeiv::System#set(func, jac, parameters...) This method sets or resets the procedures to evaluate the function and jacobian, and the constant parameters. --- GSL::Odeiv::System#set_params(...) Set the constant parameters of the function. --- GSL::Odeiv::System#function --- GSL::Odeiv::System#func --- GSL::Odeiv::System#jacobian --- GSL::Odeiv::System#jac Return Proc objects --- GSL::Odeiv::System#dimension --- GSL::Odeiv::System#dim === GSL::Odeiv::Control --- GSL::Odeiv::Control.standard_new(epsabs, epsrel, a_y, a_dydt) --- GSL::Odeiv::Control.alloc(epsabs, epsrel, a_y, a_dydt) The standard control object is a four parameter heuristic based on absolute and relative errors ((|epsabs|)) and ((|epsrel|)), and scaling factors ((|a_y|)) and ((|a_dydt|)) for the system state ((|y(t)|)) and derivatives ((|y'(t)|)) respectively. --- GSL::Odeiv::Control.y_new(epsabs, epsrel) This method creates a new control object which will keep the local error on each step within an absolute error of ((|epsabs|)) and relative error of ((|epsrel|)) with respect to the solution ((|y_i(t)|)). This is equivalent to the standard control object with ((|a_y=1|)) and ((|a_dydt=0|)). --- GSL::Odeiv::Control.yp_new(epsabs, epsrel) This method creates a new control object which will keep the local error on each step within an absolute error of ((|epsabs|)) and relative error of ((|epsrel|)) with respect to the derivatives of the solution ((|y'_i(t)|)). This is equivalent to the standard control object with ((|a_y=0|)) and ((|a_dydt=1|)). --- GSL::Odeiv::Control.alloc(epsabs, epsrel, a_y, a_dydt, vscale, dim) This creates a new control object which uses the same algorithm as (({GSL::Odeiv::Control.standard_new})) but with an absolute error which is scaled for each component by the (({GSL::Vector})) object ((|vscale|)). --- GSL::Odeiv::Control#init(epsabs, epsrel, a_y, a_dydt) This method initializes the controler with the parameters ((|epsabs|)) (absolute error), ((|epsrel|)) (relative error), ((|a_y|)) (scaling factor for y) and ((|a_dydt|)) (scaling factor for derivatives). --- GSL::Odeiv::Control#name --- GSL::Odeiv::Control#hadjust(step, y0, yerr, dydt, h) This method adjusts the step-size ((|h|)) using the control function object, and the current values of ((|y|)), ((|yerr|)) and ((|dydt|)). The stepping function ((|step|)) is also needed to determine the order of the method. On output, an array of two elements [((|hadj, status|))] is returned: If the error in the y-values ((|yerr|)) is found to be too large then the step-size ((|h|)) is reduced and the method returns [((|hadj, status|))=(({GSL::ODEIV::HADJ_DEC}))]. If the error is sufficiently small then ((|h|)) may be increased and [((|hadj, status|))=(({GSL::ODEIV::HADJ_INC}))] is returned. The method returns [((|hadj, status|))=(({GSL::ODEIV::HADJ_NIL}))] if the step-size is unchanged. The goal of the method is to estimate the largest step-size which satisfies the user-specified accuracy requirements for the current point. === GSL::Odeiv::Evolve The higher level of the system is the (({GSL::Evolve})) class which combines the results of a stepper and controler to reliably advance the solution forward over an interval (({(t_0, t_1)})). If the controler signals that the step-size should be decreased the (({GSL::Evolve})) object backs out of the current step and tries the proposed smaller step-size. This process is continued until an acceptable step-size is found. --- GSL::Odeiv::Evolve.alloc(dim) These create a (({GSL::Evolve})) object for a system of ((|dim|)) dimensions. --- GSL::Odeiv::Evolve#reset This method resets the GSL::Evolve object. It should be used whenever the next use of e will not be a continuation of a previous step. --- GSL::Odeiv::Evolve#apply(evolve, control, step, sys, t, t1, h, y) This method advances the system ((|sys|)) from time ((|t|)) and position ((|y|)) using the stepping function ((|step|)). The initial step-size is taken as ((|h|)). The maximum time ((|t1|)) is guaranteed not to be exceeded by the time-step. On output, an array of three elements is returned, [((|tnext, hnext, status|))], where ((|tnext|)) is the time advanced, ((|hnext|)) is the step-size for the next step, and ((|status|)) is an error code retunred by (({gsl_odeiv_evolve_apply()})) function. On the final time-step the value of ((|tnext|)) will be set to ((|t1|)) exactly. --- GSL::Odeiv::Evolve#count === GSL::Odeiv::Solver This is the highest level interface to solve ODE system, which contains System, Step, Control, and Evolve classes. --- GSL::Odeiv::Solver.alloc(T, cary, fac, dim) This creates a ODE solver with the algorithm type ((|T|)) for the system of dimention ((|dim|)). Here ((|cary|)) is an array as an argument for the (({GSL::Odeive:Control})) constructor. * Ex1 solver = Odeiv::Solver.alloc(Odeiv::Step::RKF45, [1e-6, 0.0], func, dim) * Type: RKF45, * Control: epsabs = 1e-6, epsrel = 0.0, a_y = 1, a_dydt = 0 * System: function = ((|func|)), jacobian = ((|nil|)) * Dimension: dim * Ex2: solver = Odeiv::Solver.alloc(Odeiv::Step::BSIMP, [1e-6, 0.0, 1, 0], func, jac, dim) * Type: BSIMP, * Control: epsabs = 1e-6, epsrel = 0.0, a_y = 1, a_dydt = 0 * System: function = ((|func|)), jacobian = ((|jac|)) * Dimension: dim --- GSL::Odeiv:::Solver#reset Reset the solver elements (step, evolve) --- GSL::Odeiv:::Solver#step --- GSL::Odeiv:::Solver#control --- GSL::Odeiv:::Solver#evolve --- GSL::Odeiv:::Solver#system Access to the solver elements. --- GSL::Odeiv::System#set_params(...) Set the constant parameters of the function to solve. --- GSL::Odeiv:::Solver#apply(t, t1, h, y) This method advances the system from time ((|t|)) and position ((|y|)) ((({GSL::Vector})) object) using the stepping function. On output, the new time and position are returned as an array [((|tnext, hnext, status|))], i.e. ((|t, y|)) themselves are not modified by this method. The maximum time ((|t1|)) is guaranteed not to be exceeded by the time-step. On the final time-step the value of ((|tnext|)) will be set to ((|t1|)) exactly. == Example The following program solves the second-order nonlinear Van der Pol oscillator equation, as found in the GSL manual, x"(t) + \mu x'(t) (x(t)^2 - 1) + x(t) = 0, This can be converted into a first order system suitable for use with the routines described in this chapter by introducing a separate variable for the velocity, y = x'(t), * x' = y * y' = -x + \mu y (1-x^2) require("gsl") include Odeiv dim = 2 # dimension of the system # Proc object to calculate the derivatives func = Proc.new { |t, y, dydt, mu| dydt[0] = y[1] dydt[1] = -y[0] - mu*y[1]*(y[0]*y[0] - 1.0) } # Create the solver solver = Solver.alloc(Step::RKF45, [1e-6, 0.0], func, dim) mu = 10.0 solver.set_params(mu) t = 0.0 # initial time t1 = 100.0 # end time h = 1e-6 # initial step y = Vector.alloc([1.0, 0.0]) # initial value while t < t1 t, h, status = solver.apply(t, t1, h, y) break if status != GSL::SUCCESS printf("%.5e %.5e %.5e %.5e\n", t, y[0], y[1], h) end (()) (()) (()) (()) =end