subroutine lmstr1(fcn,m,n,x,fvec,fjac,ldfjac,tol,info,ipvt,wa,
* lwa)
integer m,n,ldfjac,info,lwa
integer ipvt(n)
double precision tol
double precision x(n),fvec(m),fjac(ldfjac,n),wa(lwa)
external fcn
c **********
c
c subroutine lmstr1
c
c the purpose of lmstr1 is to minimize the sum of the squares of
c m nonlinear functions in n variables by a modification of
c the levenberg-marquardt algorithm which uses minimal storage.
c this is done by using the more general least-squares solver
c lmstr. the user must provide a subroutine which calculates
c the functions and the rows of the jacobian.
c
c the subroutine statement is
c
c subroutine lmstr1(fcn,m,n,x,fvec,fjac,ldfjac,tol,info,
c ipvt,wa,lwa)
c
c where
c
c fcn is the name of the user-supplied subroutine which
c calculates the functions and the rows of the jacobian.
c fcn must be declared in an external statement in the
c user calling program, and should be written as follows.
c
c subroutine fcn(m,n,x,fvec,fjrow,iflag)
c integer m,n,iflag
c double precision x(n),fvec(m),fjrow(n)
c ----------
c if iflag = 1 calculate the functions at x and
c return this vector in fvec.
c if iflag = i calculate the (i-1)-st row of the
c jacobian at x and return this vector in fjrow.
c ----------
c return
c end
c
c the value of iflag should not be changed by fcn unless
c the user wants to terminate execution of lmstr1.
c in this case set iflag to a negative integer.
c
c m is a positive integer input variable set to the number
c of functions.
c
c n is a positive integer input variable set to the number
c of variables. n must not exceed m.
c
c x is an array of length n. on input x must contain
c an initial estimate of the solution vector. on output x
c contains the final estimate of the solution vector.
c
c fvec is an output array of length m which contains
c the functions evaluated at the output x.
c
c fjac is an output n by n array. the upper triangle of fjac
c contains an upper triangular matrix r such that
c
c t t t
c p *(jac *jac)*p = r *r,
c
c where p is a permutation matrix and jac is the final
c calculated jacobian. column j of p is column ipvt(j)
c (see below) of the identity matrix. the lower triangular
c part of fjac contains information generated during
c the computation of r.
c
c ldfjac is a positive integer input variable not less than n
c which specifies the leading dimension of the array fjac.
c
c tol is a nonnegative input variable. termination occurs
c when the algorithm estimates either that the relative
c error in the sum of squares is at most tol or that
c the relative error between x and the solution is at
c most tol.
c
c info is an integer output variable. if the user has
c terminated execution, info is set to the (negative)
c value of iflag. see description of fcn. otherwise,
c info is set as follows.
c
c info = 0 improper input parameters.
c
c info = 1 algorithm estimates that the relative error
c in the sum of squares is at most tol.
c
c info = 2 algorithm estimates that the relative error
c between x and the solution is at most tol.
c
c info = 3 conditions for info = 1 and info = 2 both hold.
c
c info = 4 fvec is orthogonal to the columns of the
c jacobian to machine precision.
c
c info = 5 number of calls to fcn with iflag = 1 has
c reached 100*(n+1).
c
c info = 6 tol is too small. no further reduction in
c the sum of squares is possible.
c
c info = 7 tol is too small. no further improvement in
c the approximate solution x is possible.
c
c ipvt is an integer output array of length n. ipvt
c defines a permutation matrix p such that jac*p = q*r,
c where jac is the final calculated jacobian, q is
c orthogonal (not stored), and r is upper triangular.
c column j of p is column ipvt(j) of the identity matrix.
c
c wa is a work array of length lwa.
c
c lwa is a positive integer input variable not less than 5*n+m.
c
c subprograms called
c
c user-supplied ...... fcn
c
c minpack-supplied ... lmstr
c
c argonne national laboratory. minpack project. march 1980.
c burton s. garbow, dudley v. goetschel, kenneth e. hillstrom,
c jorge j. more
c
c **********
integer maxfev,mode,nfev,njev,nprint
double precision factor,ftol,gtol,xtol,zero
data factor,zero /1.0d2,0.0d0/
info = 0
c
c check the input parameters for errors.
c
if (n .le. 0 .or. m .lt. n .or. ldfjac .lt. n .or. tol .lt. zero
* .or. lwa .lt. 5*n + m) go to 10
c
c call lmstr.
c
maxfev = 100*(n + 1)
ftol = tol
xtol = tol
gtol = zero
mode = 1
nprint = 0
call lmstr(fcn,m,n,x,fvec,fjac,ldfjac,ftol,xtol,gtol,maxfev,
* wa(1),mode,factor,nprint,info,nfev,njev,ipvt,wa(n+1),
* wa(2*n+1),wa(3*n+1),wa(4*n+1),wa(5*n+1))
if (info .eq. 8) info = 4
10 continue
return
c
c last card of subroutine lmstr1.
c
end