Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to fit the information from the G function of my data to the following mathematical mode: y = A / ((1 + (B^2)*(x^2))^((C+1)/2)) . The shape of this graph can be seen here:

http://www.wolframalpha.com/input/?i=y+%3D+1%2F+%28%281+%2B+%282%5E2%29*%28x%5E2%29%29%5E%28%282%2B1%29%2F2%29%29

Here's a basic example of what I've been doing:

data(simdat)

library(spatstat)

simdat.Gest <- Gest(simdat) #Gest is a function within spatstat (explained below)

Gvalues <- simdat.Gest$rs

Rvalues <- simdat.Gest$r

GvsR_dataframe <- data.frame(R = Rvalues, G = rev(Gvalues))

themodel <- nls(rev(Gvalues) ~ (1 / (1 + (B^2)*(R^2))^((C+1)/2)), data = GvsR_dataframe, start = list(B=0.1, C=0.1), trace = FALSE)

"Gest" is a function found within the 'spatstat' library. It is the G function, or the nearest-neighbour function, which displays the distance between particles on the independent axis, versus the probability of finding a nearest neighbour particle on the dependent axis. Thus, it begins at y=0 and hits a saturation point at y=1.

If you plot simdat.Gest, you'll notice that the curve is 's' shaped, meaning that it starts at y = 0 and ends up at y = 1. For this reason, I reveresed the vector Gvalues, which are the dependent variables. Thus, the information is in the correct orientation to be fitted the above model.

You may also notice that I've automatically set A = 1. This is because G(r) always saturates at 1, so I didn't bother keeping it in the formula.

My problem is that I keep getting errors. For the above example, I get this error:

Error in nls(rev(Gvalues) ~ (1/(1 + (B^2) * (R^2))^((C + 1)/2)), data = GvsR_dataframe,  : 
  singular gradient

I've also been getting this error:

Error in nls(Gvalues1 ~ (1/(1 + (B^2) * (x^2))^((C + 1)/2)), data = G_r_dataframe,  : 
  step factor 0.000488281 reduced below 'minFactor' of 0.000976562

I haven't a clue as to where the first error is coming from. The second, however, I believe was occurring because I did not pick suitable starting values for B and C.

I was hoping that someone could help me figure out where the first error was coming from. Also, what is the most effective way to pick starting values to avoid the second error?

Thanks!

share|improve this question
    
When you type simdat.Gest <- Gest(simdat) you are telling us you have a function named Gest. But you have not given it to us. I don't think it would be that difficult to create a test dataset using rnorm, although ideally we would be given say the first twenty rows, but we really do need to know what Gest is doing. –  BondedDust Jun 27 '12 at 21:17
    
You are also using a different name ('Gvalues') in that formula than is being used in the data.frame ('G') –  BondedDust Jun 27 '12 at 21:22
    
That was my mistake, I've edited the post now. "Gest" is a function found within the 'spatstat' library. Gest is the nearest-neighbour function which displays the distance between particles on the independent axis, versus the probability of finding a nearest neighbour particle on the dependent axis. Thus, it begins at y=0 and hits a saturation point at y=1. –  MikeZ Jun 28 '12 at 13:15
    
Also, I've tried using nls.lm, and it's been giving me grief, as well. –  MikeZ Jul 5 '12 at 17:31
add comment

1 Answer

up vote 2 down vote accepted

As noted your problem is most likely the starting values. There are two strategies you could use:

  1. Use brute force to find starting values. See package nls2 for a function to do this.
  2. Try to get a sensible guess for starting values. Depending on your values it could be possible to linearize the model.

G = (1 / (1 + (B^2)*(R^2))^((C+1)/2))

ln(G)=-(C+1)/2*ln(B^2*R^2+1)

If B^2*R^2 is large, this becomes approx. ln(G) = -(C+1)*(ln(B)+ln(R)), which is linear.

If B^2*R^2 is close to 1, it is approx. ln(G) = -(C+1)/2*ln(2), which is constant.

(Please check for errors, it was late last night due to the soccer game.)

Edit after additional information has been provided: The data looks like it follows a cumulative distribution function. If it quacks like a duck, it most likely is a duck. And in fact ?Gest states that a CDF is estimated.

library(spatstat)
data(simdat)
simdat.Gest <- Gest(simdat)
Gvalues <- simdat.Gest$rs
Rvalues <- simdat.Gest$r
plot(Gvalues~Rvalues)

#let's try the normal CDF
fit <- nls(Gvalues~pnorm(Rvalues,mean,sd),start=list(mean=0.4,sd=0.2))
summary(fit)
lines(Rvalues,predict(fit))
#Looks not bad. There might be a better model, but not the one provided in the question.
share|improve this answer
    
That is VERY helpful, thank you! I may explore other models, and try to optimize the one I was working with earlier, but this presents a great starting point. –  MikeZ Jun 28 '12 at 18:15
    
Roland, Modelling my information with the CDF has proven to be much more simple, but does not present as much useful information as I had hoped. The function in my initial question, were I able to model it with the data, would present more useful info. Do you know of any strategies I could use to find the source of the errors i've stated above? –  MikeZ Jul 5 '12 at 17:30
    
Trying to fit a model that simply does not describe the "shape" of the data very well usually poses optimization problems. That is essentially what the error messages tell you. Choice of model for nonlinear regression should (I would nearly say must) be based on physical or mathematical considerations. What is your justification for your choice of model? I suspect that you are trying to solve some unknown other problem, which could be better solved with other tools. –  Roland Jul 5 '12 at 18:26
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.