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Explanation

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 lm().

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 lm() and 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 x0.

Questions

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?

Reproducible example

(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
share|improve this question
    
Use the default algorithm (i.e., Gauss-Newton algorithm) for that. – Metrics Mar 8 '14 at 22:13
up vote 0 down vote accepted

Regarding the nls model it seems that the desired model has no linear components since x0 is fixed so there is no reason to use plinear in the first place:

temp2.nls <- nls(temp.theta ~ x0 * exp(-k*l), start=list(k=k))

Regarding whether lm or nls is better have a look at the residuals. Looking at the plots of the residuals, the residual of the first point seems to stick out suggesting it may not follow either model; however, with only 5 points we can't really say too much.

plot(resid(temp.lm), pch = 20, cex = 2, main = "lm Residuals")
plot(resid(temp2.nls), pch = 20, cex = 2, main = "nls Residuals")

enter image description here

enter image description here

share|improve this answer
    
This is just a randomly chosen slice of data from a physical experiment where five curves were measured for different thiknesses of a material hence five points for every slice which by fitting all slices one by one (as shown here on one of them) produce another relationship. I am working on a much more complex question regarding this on stats.SE where most of it belongs, I think. – VaNa Mar 9 '14 at 3:10
    
If data is available look at the residuals for both models and if the residuals form a ribbon around zero for one of the models but fan out or fan in for the other then the ribbon conforms better to the assumption of constant variance. – G. Grothendieck Mar 9 '14 at 4:09
    
I've asked a question about this on stats.SE. the residual analysis is hard since I have more than 300 of these fits and don't know which numbers to look for. – VaNa Mar 9 '14 at 4:53
    
Try plotting the points and both model fits all on the same graph. – G. Grothendieck Mar 9 '14 at 12:22

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