I am trying to fit an exponential curve to data in form
theta = x0 * exp(-kappa*l).
I do it firstly with
linear = lm( I(-log(temp.theta/x0)) ~ l + 0 ) where I get coefficient (
k = coef(linear)) and then with
nls(temp.theta ~ I(x0 * exp(-k*l)) + 0, algorithm = "plinear" , start = list(k=k)) because I am not sure whether errors have the right nature with the
That decision came from reading a few Q&A's at stats.stackexchange about models where they discussed additive vs. multiplicative noise (=> error estimates?), which I haven't quite understand as I have just really basic knowledge of statistics. And since
nls() give me different error estimates I intuitively think the latter could be more accurate.
The problem is the
nls(... , algorithm="plinear") produces the coefficient which I want, but also the
.lin thing which I understand to be multiplying the whole right side of the equation and hence messing up my model as it has sense only with intercept at
Is there a way to set
.lin = 1 or somehow turn it off?
Or alternatively: Is the
lm() model sufficient for getting me reasonable error estimation?
(sorry for not including one right away, I thought it's better to ask in an abstract form):
l = c(0.001 , 0.002 , 0.003 , 0.004 , 0.005) temp.theta = c(84.405 , 70.265 , 58.689 , 49.428 , 41.188) x0 = 100 temp.lm = lm( I(-log(temp.theta/x0)) ~ l + 0 ) k=coef(temp.lm) temp.nls = nls(temp.theta ~ I(x0 * exp(-k*l)) + 0, algorithm="plinear", start=list(k=k)) kappa=coef(temp.nls) kappa