0
library(ggplot2)

dat <- structure(list(y = c(52L, 63L, 59L, 58L, 57L, 54L, 27L, 20L, 15L, 27L, 27L, 26L, 70L, 70L, 70L, 70L, 70L, 70L, 45L, 42L, 41L, 55L, 45L, 39L, 51L, 
                        64L, 57L, 39L, 59L, 37L, 44L, 44L, 38L, 57L, 50L, 56L, 66L, 66L, 64L, 64L, 60L, 55L, 52L, 57L, 47L, 57L, 64L, 63L, 49L, 49L, 
                        56L, 55L, 57L, 42L, 60L, 53L, 53L, 57L, 56L, 54L, 42L, 45L, 34L, 52L, 57L, 50L, 60L, 59L, 52L, 42L, 45L, 47L, 45L, 51L, 39L, 
                        38L, 42L, 33L, 62L, 57L, 65L, 44L, 44L, 39L, 46L,  49L, 52L, 44L, 43L, 38L), 
                  x = c(122743L, 132300L, 146144L, 179886L, 195180L, 233605L, 1400L, 1400L, 3600L, 5000L, 14900L, 16000L, 71410L, 85450L, 106018L, 
                        119686L, 189746L, 243171L, 536545L, 719356L, 830031L, 564546L, 677540L, 761225L, 551561L, 626799L, 68618L, 1211267L, 1276369L,
                        1440113L, 1153720L, 1244575L, 1328641L, 610452L, 692624L, 791953L, 4762522L, 5011232L, 5240402L, 521339L, 
                        560098L, 608641L, 4727833L, 4990042L, 5263899L, 1987296L, 2158704L, 2350927L, 7931905L, 8628608L, 8983683L, 2947957L, 3176995L, 3263118L, 
                        55402L, 54854L, 55050L, 52500L, 72000L, 68862L, 1158244L, 1099976L, 1019490L, 538146L, 471219L, 437954L, 863592L, 661055L, 
                        548097L, 484450L, 442643L, 404487L, 1033728L, 925514L, 854793L, 371420L, 285257L, 260157L, 2039241L, 2150710L, 1898614L, 
                        1175287L, 1495433L, 1569586L, 2646966L, 3330486L, 3282677L, 745784L, 858574L, 1119671L)), 
                class = "data.frame", row.names = c(NA, -90L))

 ggplot(dat, aes(x = x, y = y)) + geom_point()

enter image description here

The relationship seems like a non-linear relationship. Hence I will fitted a model where I logged y and x

mod.lm <- lm(log(y) ~ log(x), data = dat)
ggplot(dat, aes(x = log(x), y = log(y))) + geom_point() + geom_smooth(method = "lm") 

enter image description here

However, I can see that for lower values, the log-transformation results in big differences as shown by the residuals. I then moved to non linear least square method. I have not used this before but using this post

Why is nls() giving me "singular gradient matrix at initial parameter estimates" errors?

  c.0 <- min(dat$y) * 0.5
  model.0 <- lm(log(y - c.0) ~ x, data = dat)
  start <- list(a = exp(coef(model.0)[1]), b = coef(model.0)[2], c = c.0)
  model <- nls(y ~ a * exp(b * x) + c, data = dat, start = start)

  Error in nls(y ~ a * exp(b * x) + c, data = dat, start = start) : 
    step factor 0.000488281 reduced below 'minFactor' of 0.000976562

Can anyone advise me what does this error mean and how to fit a nls model to the above data?

migrated from stats.stackexchange.com Oct 23 '18 at 0:29

This question came from our site for people interested in statistics, machine learning, data analysis, data mining, and data visualization.

  • I think this belongs on stackoverflow. You may still not get a very good answer. Do you know how to debug models like this? E.g. fitting 1-step, printing a trace, using an MCMC method, etc? – AdamO Oct 22 '18 at 14:31
  • Not really. nls is quite new to me and I am reading around it but it might take me a while to get my head around how to debug this kind of error – Crop89 Oct 22 '18 at 14:34
  • This error message is discussed in about 20 posts on our site. You can find them with this search: stats.stackexchange.com/…. – whuber Oct 22 '18 at 15:18
  • 1
    One of the best simple no-log-used equations I could find was a standard geometric equation plus offset, "y = a * (x ^ (b*x)) + offset", with fitted parameters a = -3.5733821373745727E+01, b = -5.0891662732768598E-06, and offset = 5.2343614684066324E+01 giving an RMSE of 9.47 and R-squared of 0.349. – James Phillips Oct 22 '18 at 17:35
  • @JamesPhillips thank you. If you could post this as an answer, I will be happy to review it and accept it – Crop89 Oct 23 '18 at 7:12
1

In your case nls get in problems as your starting values are not good and you introduced the coefficient c which is not there in the linearized form. To fit your nls you can do it the following way, with better staring values and removing the coefficient c:

mod.glm <- glm(y ~ x, dat=dat, family=poisson(link = "log"))
start <- list(a = coef(mod.glm)[1], b = coef(mod.glm)[2])
mod.nls <- nls(y ~ exp(a + b * x), data = dat, start = start)

I would recommend to use glm, as shown above, instead of nls to find the coefficients.

If the estimate of the linearized model (mod.lm) should not have a bias you need to adjust it.

mod.lm <- lm(log(y) ~ log(x), data = dat)
mean(dat$y) #50.44444
mean(predict(mod.glm, type="response")) #50.44444
mean(predict(mod.nls)) #50.44499
mean(exp(predict(mod.lm))) #49.11622 !
f <- log(mean(dat$y) / mean(exp(predict(mod.lm)))) #bias corection for a
mean(exp(coef(mod.lm)[1] + f + coef(mod.lm)[2]*log(dat$x))) #50.44444

In case you want to get the coefficients given from James Phillips in the comments by your own, you can try:

mod.nlsJP <- nls(y ~ a * (x^(b*x)) + offset, data=dat, start=list(a=-30, b=-5e-6, offset=50))

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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