Lsqcurvefit Cannot Continue User Function is Returning Inf or Nan Values

lsqcurvefit

Solve nonlinear curve-fitting (data-fitting) problems in the least squares sense. That is, given input data xdata, and the observed output ydata, find coefficients x that "best-fit" the equation F(x, xdata)

where xdata and ydata are vectors and F(x, xdata) is a vector valued function.

The function lsqcurvefit uses the same algorithm as lsqnonlin. Its purpose is to provide an interface designed specifically for data-fitting problems.

Syntax

    x = lsqcurvefit(fun,x0,xdata,ydata) x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub) x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub,options) x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub,options,P1,P2,...) [x,resnorm] = lsqcurvefit(...) [x,resnorm,residual] = lsqcurvefit(...) [x,resnorm,residual,exitflag] = lsqcurvefit(...) [x,resnorm,residual,exitflag,output] = lsqcurvefit(...) [x,resnorm,residual,exitflag,output,lambda] = lsqcurvefit(...) [x,resnorm,residual,exitflag,output,lambda,jacobian] =     lsqcurvefit(...)        

Description

lsqcurvefit solves nonlinear data-fitting problems. lsqcurvefit requires a user-defined function to compute the vector-valued function F(x, xdata). The size of the vector returned by the user-defined function must be the same as the size of ydata.

x = lsqcurvefit(fun,x0,xdata,ydata) starts at x0 and finds coefficients x to best fit the nonlinear function fun(x,xdata) to the data ydata (in the least squares sense). ydata must be the same size as the vector (or matrix) F returned by fun.

x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub) defines a set of lower and upper bounds on the design variables, x, so that the solution is always in the range lb <= x <= ub.

x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub,options) minimizes with the optimization parameters specified in the structure options. Pass empty matrices for lb and ub if no bounds exist.

x = lsqcurvefit(fun,x0,xdata,ydata,lb,ub,options,P1,P2,...) passes the problem-dependent parameters P1, P2, etc., directly to the function fun. Pass an empty matrix for options to use the default values for options.

[x,resnorm] = lsqcurvefit(...) returns the value of the squared 2-norm of the residual at x: sum{(fun(x,xdata)-ydata).^2}.

[x,resnorm,residual] = lsqcurvefit(...) returns the value of the residual, fun(x,xdata)-ydata, at the solution x.

[x,resnorm,residual,exitflag] = lsqcurvefit(...) returns a value exitflag that describes the exit condition.

[x,resnorm,residual,exitflag,output] = lsqcurvefit(...) returns a structure output that contains information about the optimization.

[x,resnorm,residual,exitflag,output,lambda] = lsqcurvefit(...) returns a structure lambda whose fields contain the Lagrange multipliers at the solution x.

[x,resnorm,residual,exitflag,output,lambda,jacobian] = 99 99lsqcurvefit(...) returns the Jacobian of fun at the solution x.

Arguments

Input Arguments. Table 4-1, Input Arguments, contains general descriptions of arguments passed in to lsqcurvefit. This section provides function-specific details for fun and options:

fun
The function to be fit. fun is a function that takes a vector x and returns a vector F, the objective functions evaluated at x. The function fun can be specified as a function handle.
    x = lsqcurvefit(@myfun,x0,xdata,ydata)                  
where myfun is a MATLAB function such as
    function F = myfun(x,xdata) F = ...            % Compute function values at x                  
fun can also be an inline object.
    f = inline('x(1)*xdata.^2+x(2)*sin(xdata)',...            'x','xdata'); x = lsqcurvefit(f,x0,xdata,ydata);                  
If the Jacobian can also be computed and options.Jacobian is 'on', set by
    options = optimset('Jacobian','on')                  
then the function fun must return, in a second output argument, the Jacobian value J, a matrix, at x. Note that by checking the value of nargout the function can avoid computing J when fun is called with only one output argument (in the case where the optimization algorithm only needs the value of F but not J).
    function [F,J] = myfun(x,xdata) F = ...          % objective function values at x if nargout > 1   % two output arguments    J = ...   % Jacobian of the function evaluated at x end                  
If fun returns a vector (matrix) of m components and x has length n, where n is the length of x0, then the Jacobian J is an m-by-n matrix where J(i,j) is the partial derivative of F(i) with respect to x(j). (Note that the Jacobian J is the transpose of the gradient of F.)
options
Options provides the function-specific details for the options parameters.

Output Arguments. Table 4-2, Output Arguments, contains general descriptions of arguments returned by lsqcurvefit. This section provides function-specific details for exitflag, lambda, and output:

exitflag
Describes the exit condition:

> 0
The function converged to a solution x.

0
The maximum number of function evaluations or iterations was exceeded.

< 0
The function did not converge to a solution.
lambda
Structure containing the Lagrange multipliers at the solution x (separated by constraint type). The fields of the structure are:

lower
Lower bounds lb

upper
Upper bounds ub
output
Structure containing information about the optimization. The fields of the structure are:

iterations
Number of iterations taken.

funcCount
Number of function evaluations.

algorithm
Algorithm used.

cgiterations
The number of PCG iterations (large-scale algorithm only).

stepsize
The final step size taken (medium-scale algorithm only).

firstorderopt
Measure of first-order optimality (large-scale algorithm only)
For large-scale bound constrained problems, the first-order optimality is the infinity norm of v.*g, where v is defined as in Box Constraints, and g is the gradient g = J T F (see Nonlinear Least Squares).

    Note    The sum of squares should not be formed explicitly. Instead, your function should return a vector of function values. See the examples below.

Options

Optimization options parameters used by lsqcurvefit. Some parameters apply to all algorithms, some are only relevant when using the large-scale algorithm, and others are only relevant when using the medium-scale algorithm.You can use optimset to set or change the values of these fields in the parameters structure, options. See Table 4-3, Optimization Options Parameters,, for detailed information.

We start by describing the LargeScale option since it states a preference for which algorithm to use. It is only a preference since certain conditions must be met to use the large-scale or medium-scale algorithm. For the large-scale algorithm, the nonlinear system of equations cannot be under-determined; that is, the number of equations (the number of elements of F returned by fun) must be at least as many as the length of x. Furthermore, only the large-scale algorithm handles bound constraints:

LargeScale
Use large-scale algorithm if possible when set to 'on'. Use medium-scale algorithm when set to 'off'.

Medium-Scale and Large-Scale Algorithms. These parameters are used by both the medium-scale and large-scale algorithms:

Diagnostics
Print diagnostic information about the function to be minimized.
Display
Level of display. 'off' displays no output; 'iter' displays output at each iteration; 'final' (default) displays just the final output.
Jacobian
If 'on', lsqcurvefit uses a user-defined Jacobian (defined in fun), or Jacobian information (when using JacobMult), for the objective function. If 'off', lsqcurvefit approximates the Jacobian using finite differences.
MaxFunEvals
Maximum number of function evaluations allowed.
MaxIter
Maximum number of iterations allowed.
TolFun
Termination tolerance on the function value.
TolX
Termination tolerance on x.

Large-Scale Algorithm Only. These parameters are used only by the large-scale algorithm:

JacobMult
Function handle for Jacobian multiply function. For large-scale structured problems, this function computes the Jacobian matrix products J*Y, J'*Y, or J'*(J*Y) without actually forming J. The function is of the form
    W = jmfun(Jinfo,Y,flag,p1,p2,...)                  
where Jinfo and the additional parameters p1,p2,... contain the matrices used to compute J*Y (or J'*Y, or J'*(J*Y)). The first argument Jinfo must be the same as the second argument returned by the objective function fun.
    [F,Jinfo] = fun(x,p1,p2,...)                  
The parameters p1,p2,... are the same additional parameters that are passed to lsqcurvefit (and to fun).
    lsqcurvefit(fun,...,options,p1,p2,...)                  
Y is a matrix that has the same number of rows as there are dimensions in the problem. flag determines which product to compute. If flag == 0 then W = J'*(J*Y). If flag > 0 then W = J*Y. If flag < 0 then W = J'*Y. In each case, J is not formed explicitly. lsqcurvefit uses Jinfo to compute the preconditioner.

    Note 'Jacobian' must be set to 'on' for Jinfo to be passed from fun to jmfun.

See Nonlinear Minimization with a Dense but Structured Hessian and Equality Constraints for a similar example.

JacobPattern
Sparsity pattern of the Jacobian for finite-differencing. If it is not convenient to compute the Jacobian matrix J in fun, lsqcurvefit can approximate J via sparse finite-differences provided the structure of J, i.e., locations of the nonzeros, is supplied as the value for JacobPattern. In the worst case, if the structure is unknown, you can set JacobPattern to be a dense matrix and a full finite-difference approximation is computed in each iteration (this is the default if JacobPattern is not set). This can be very expensive for large problems so it is usually worth the effort to determine the sparsity structure.
MaxPCGIter
Maximum number of PCG (preconditioned conjugate gradient) iterations (see the Algorithm section below).
PrecondBandWidth
Upper bandwidth of preconditioner for PCG. By default, diagonal preconditioning is used (upper bandwidth of 0). For some problems, increasing the bandwidth reduces the number of PCG iterations.
TolPCG
Termination tolerance on the PCG iteration.
TypicalX
Typical x values.

Medium-Scale Algorithm Only. These parameters are used only by the medium-scale algorithm:

DerivativeCheck

Compare user-supplied derivatives (Jacobian) to finite-differencing derivatives.

DiffMaxChange

Maximum change in variables for finite-differencing.

DiffMinChange

Minimum change in variables for finite-differencing.

LevenbergMarquardt

Choose Levenberg-Marquardt over Gauss-Newton algorithm.

LineSearchType

Line search algorithm choice.

Examples

Vectors of data xdata and ydata are of length n. You want to find coefficients x to find the best fit to the equation

that is, you want to minimize

where F(x,xdata) = x(1)*xdata.^2 + x(2)*sin(xdata) + x(3)*xdata.^3, starting at the point x0 = [0.3, 0.4, 0.1].

First, write an M-file to return the value of F (F has n components).

    function F = myfun(x,xdata) F = x(1)*xdata.^2 + x(2)*sin(xdata) + x(3)*xdata.^3;        

Next, invoke an optimization routine:

    % Assume you determined xdata and ydata experimentally xdata = [3.6 7.7 9.3 4.1 8.6 2.8 1.3 7.9 10.0 5.4]; ydata = [16.5 150.6 263.1 24.7 208.5 9.9 2.7 163.9 325.0 54.3]; x0 = [10, 10, 10]                    % Starting guess [x,resnorm] = lsqcurvefit(@myfun,x0,xdata,ydata)        

Note that at the time that lsqcurvefit is called, xdata and ydata are assumed to exist and are vectors of the same size. They must be the same size because the value F returned by fun must be the same size as ydata.

After 33 function evaluations, this example gives the solution

    x =  0.2269    0.3385    0.3021 % residual or sum of squares resnorm =       6.2950        

The residual is not zero because in this case there was some noise (experimental error) in the data.

Algorithm

Large-Scale Optimization. By default lsqcurvefit chooses the large-scale algorithm. This algorithm is a subspace trust region method and is based on the interior-reflective Newton method described in [1], [2]. Each iteration involves the approximate solution of a large linear system using the method of preconditioned conjugate gradients (PCG). See Trust Region Methods for Nonlinear Minimization, and Preconditioned Conjugate Gradients in the "Large-Scale Algorithms" section.

Medium-Scale Optimization.lsqcurvefit with options.LargeScale set to 'off' uses the Levenberg-Marquardt method with line-search [4], [5], [6]. Alternatively, a Gauss-Newton method [3] with line-search may be selected. The choice of algorithm is made by setting options.LevenbergMarquardt. Setting options.LevenbergMarquardt to 'off' (and options.LargeScale to 'off') selects the Gauss-Newton method, which is generally faster when the residual

is small.

The default line search algorithm, i.e., options.LineSearchType set to 'quadcubic', is a safeguarded mixed quadratic and cubic polynomial interpolation and extrapolation method. A safeguarded cubic polynomial method can be selected by setting options.LineSearchType to 'cubicpoly'. This method generally requires fewer function evaluations but more gradient evaluations. Thus, if gradients are being supplied and can be calculated inexpensively, the cubic polynomial line search method is preferable. The algorithms used are described fully in Standard Algorithms.

Diagnostics

Large-Scale Optimization. The large-scale code does not allow equal upper and lower bounds. For example if lb(2)==ub(2) then lsqlin gives the error

    Equal upper and lower bounds not permitted.        

(lsqcurvefit does not handle equality constraints, which is another way to formulate equal bounds. If equality constraints are present, use fmincon, fminimax, or fgoalattain for alternative formulations where equality constraints can be included.)

Limitations

The function to be minimized must be continuous. lsqcurvefit may only give local solutions.

lsqcurvefit only handles real variables (the user-defined function must only return real values). When x has complex variables, the variables must be split into real and imaginary parts.

Large-Scale Optimization. The large-scale method for lsqcurvefit does not solve underdetermined systems; it requires that the number of equations, i.e., row dimension of F, be at least as great as the number of variables. In the underdetermined case, the medium-scale algorithm is used instead. See Table 1-4, Large-Scale Problem Coverage and Requirements for more information on what problem formulations are covered and what information must be provided.

The preconditioner computation used in the preconditioned conjugate gradient part of the large-scale method forms J T J (where J is the Jacobian matrix) before computing the preconditioner; therefore, a row of J with many nonzeros, which results in a nearly dense product J T J, may lead to a costly solution process for large problems.

If components of x have no upper (or lower) bounds, then lsqcurvefit prefers that the corresponding components of ub (or lb) be set to inf (or -inf for lower bounds) as opposed to an arbitrary but very large positive (or negative for lower bounds) number.

Currently, if the analytical Jacobian is provided in fun, the options parameter DerivativeCheck cannot be used with the large-scale method to compare the analytic Jacobian to the finite-difference Jacobian. Instead, use the medium-scale method to check the derivatives with options parameter MaxIter set to zero iterations. Then run the problem with the large-scale method.

See Also

@ (function_handle), \, lsqlin, lsqnonlin , lsqnonneg, optimset

References

[1]  Coleman, T.F. and Y. Li, "An Interior, Trust Region Approach for Nonlinear Minimization Subject to Bounds," SIAM Journal on Optimization, Vol. 6, pp. 418-445, 1996.

[2]  Coleman, T.F. and Y. Li, "On the Convergence of Reflective Newton Methods for Large-Scale Nonlinear Minimization Subject to Bounds," Mathematical Programming, Vol. 67, Number 2, pp. 189-224, 1994.

[3]  Dennis, J. E. Jr., "Nonlinear Least Squares," State of the Art in Numerical Analysis, ed. D. Jacobs, Academic Press, pp. 269-312, 1977.

[4]  Levenberg, K., "A Method for the Solution of Certain Problems in Least Squares," Quarterly Applied Math. 2, pp. 164-168, 1944.

[5]  Marquardt, D., "An Algorithm for Least Squares Estimation of Nonlinear Parameters," SIAM Journal Applied Math. Vol. 11, pp. 431-441, 1963.

[6]  More, J. J., "The Levenberg-Marquardt Algorithm: Implementation and Theory," Numerical Analysis, ed. G. A. Watson, Lecture Notes in Mathematics 630, Springer Verlag, pp. 105-116, 1977.

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