**Background**

I am trying to fit a distribution to a 95% CI and mode. The cost function that I am using solves three functions for 0: P(X=2.5 | mu, sigma)=0.025, P(X=7.5|mu, sigma)=0.975, and the mode of log-N(mu, sigma) = 3.3. note: mode of a lognormal is = $e^{\mu-\sigma^2)}$:

**Approach**

First I write a cost function, `prior`

```
prior <- function(parms) {
a <- abs(plnorm(2.5, parms[1], parms[2]) - 0.025)
b <- abs(plnorm(7.5, parms[1], parms[2]) - 0.975)
mode <- exp(parms[1] - parms[2]^2)
c <- abs(mode-3.3)
return(a + b + c)
}
```

And then I seek parameters that minimize the cost function

```
v = nlm(prior,c(log(3.3),0.14))
```

It is apparent that the function is maximized for the mode an LCL but not the UCL.

```
abs(plnorm(7.5, parms[1], parms[2]) - 0.975)
> [1] 0.02499989
```

Here is a plot with dotted lines at the desired 95%CI:

```
x <- seq(0,10,0.1)
plot(x,dlnorm(x, v$estimate[1],v$estimate[2]),type='l')
abline(v=c(2.5,7.5), lty=2) #95%CI
```

**Question**

The optimization two points closely and all of the error is in the third. However, I would like it to fit the points evenly.

How can I get the function to give equal weight to the magnitude of the *a*, *b*, and *c* terms? It appears that the function is only fitting *a* and *c*.

*note:* This question is based on one asked at [cross validated][1] except that this version is specifically about the function of R's nlm() optimization algorithm whereas the CV question is about finding the a more appropriate distribution.