0

I'd like to fit exponential curves to groups 1 & 2 in the data table shown below and obtain a new column containing the residual standard error corresponding to each group. The exponential curve should follow y=a*exp(b*x)+c

## Example data table
DT <- data.table(
x = c(1,2,3,4,5,6,7,8,1,2,3,4,5,6,7,8),
y = c(15.4,16,16.4,17.7,20,23,27,35,25.4,26,26.4,27.7,30,33,37,45),
groups = c(1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2)

However, I only know how to fit nls curves and obtain the residual standard error of single groups using the code below which estimates good starting parameters a, b, and c:

subsetDT <- DT[group == 1]
c.0 <- min(subsetDT[,y]) * 0.5
model.0 <- lm(log(y- c.0) ~ x, data=subsetDT)
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 = subsetDT, start = start, 
         control = nls.control(maxiter=500))
sigma <- summary(model)$sigma

I don't want to subset DT by group in a loop to calculate sigma and other model information.

I know that if I was using lm, I'd be able to do the following to obtain new columns containing model information:

DT[, `:=` (r.squared=summary(lm(log(y)~x))$r.squared,
           int=coef(lm(log(y)~x))[1],
           coeff=coef(lm(log(y)~x))[2]
          ), by=c("groups")]

How can I use := to fit an exponential curve and incorporate my nls parameters a, b, and c?

0

If you are looking for adding sigma, a, b, c as new columns in your original dataset, you can do the following:

DT[, c("sigma", "a", "b", "c") := {
        c.0 <- min(y) * 0.5
        model.0 <- lm(log(y - c.0) ~ x, data=.SD)
        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=.SD, 
            start=start, 
            control=nls.control(maxiter=500))
        c(.(sigma=summary(model)$sigma), as.list(coef(model)))
    },
    by=.(groups)]

output:

    x    y groups     sigma         a         b        c
 1: 1 15.4      1 0.2986243 0.5265405 0.4565363 14.56728
 2: 2 16.0      1 0.2986243 0.5265405 0.4565363 14.56728
 3: 3 16.4      1 0.2986243 0.5265405 0.4565363 14.56728
 4: 4 17.7      1 0.2986243 0.5265405 0.4565363 14.56728
 5: 5 20.0      1 0.2986243 0.5265405 0.4565363 14.56728
 6: 6 23.0      1 0.2986243 0.5265405 0.4565363 14.56728
 7: 7 27.0      1 0.2986243 0.5265405 0.4565363 14.56728
 8: 8 35.0      1 0.2986243 0.5265405 0.4565363 14.56728
 9: 1 25.4      2 0.2986243 0.5265404 0.4565363 24.56728
10: 2 26.0      2 0.2986243 0.5265404 0.4565363 24.56728
11: 3 26.4      2 0.2986243 0.5265404 0.4565363 24.56728
12: 4 27.7      2 0.2986243 0.5265404 0.4565363 24.56728
13: 5 30.0      2 0.2986243 0.5265404 0.4565363 24.56728
14: 6 33.0      2 0.2986243 0.5265404 0.4565363 24.56728
15: 7 37.0      2 0.2986243 0.5265404 0.4565363 24.56728
16: 8 45.0      2 0.2986243 0.5265404 0.4565363 24.56728
  • @Justin, cheers! – chinsoon12 Sep 26 '18 at 1:31

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.