This is a repost/adaptation of an answer of mine from r-sig-mixed models

[... The nlminb() optimizer ... is based on the PORT libraries.

The docs linked from `?nlminb`

*used to be* at `http://netlib.bell-labs.com/cm/cs/cstr/153.pdf`

: http://www.netlib.org/port/cs/cstr says

port/readme points to "Usage Summary for Selected Optimization Routines", sometimes known as PORT OPTIMIZATION DOCUMENTATION in http://netlib.bell-labs.com/cm/cs/cstr/153.ps.gz or http://netlib.bell-labs.com/cm/cs/cstr/153.pdf

... but these links are broken (`port/readme`

is still there but none of the links provided work ...).

I managed to find the docs via Google Scholar and have posted a slightly more convenient PDF version.

The only useful material I could find in these docs was:

p. 5: false convergence: the gradient ∇f(x) may be computed
incorrectly, the other stopping tolerances may be too tight, or either
f or ∇f may be discontinuous near the current iterate x.

p. 9: V(XFTOL) — V(34) is the false-convergence tolerance. A return
with IV(1) = 8 occurs if a more favorable stopping test is not
satisfied and if a step of scaled length at most V(XFTOL) is tried but
not accepted. ‘‘Scaled length’’ is in the sense of (5.1). Such a
return generally means there is an error in computing ∇f(x), or
the favorable convergence tolerances (V(RFCTOL), V(XCTOL), and
perhaps V(AFCTOL)) are too tight for the accuracy to which f(x) is
computed (see §9), or ∇f (or f itself) is discontinuous near x . An
error in computing ∇f(x) usually leads to false convergence after
only a few iterations — often in the first. Default = 100*MACHEP.

p. 13: Sometimes evaluating f(x) involves an extensive computation,
such as performing a simulation or adaptive numerical quadrature or
integrating an ordinary or partial differential equation. In such
cases the value computed for f (x), say f̃( x ), may involve
substantial error (in the eyes of the optimization algorithm). To
eliminate some ‘‘false convergence’’ messages and useless function
evaluations, it is necessary to increase the stopping tolerances and,
when finite-difference derivative approximations are used, to increase
the step-sizes used in estimating derivatives.