Thank you all for your responses.

I was trying with both programs. In R for example I was using the package `library(rriskDistributions)`

, specifically something like

```
## example with only two quantiles
q <- stats::qlnorm(p = c(0.025, 0.975), meanlog = 4, sdlog = 0.8)
old.par <- graphics::par(mfrow = c(2, 3))
get.lnorm.par(p = c(0.025, 0.975), q = q)
get.lnorm.par(p = c(0.025, 0.975), q = q, fit.weights = c(100, 1),
scaleX = c(0.1, 0.001))
get.lnorm.par(p = c(0.025, 0.975), q = q, fit.weights = c(1, 100),
scaleX = c(0.1, 0.001))
get.lnorm.par(p = c(0.025, 0.975), q = q, fit.weights = c(10, 1))
get.lnorm.par(p = c(0.025, 0.975), q = q, fit.weights = c(1, 10))
graphics::par(old.par)
```

In Stata I'm trying with GMM based on https://blog.stata.com/2015/12/03/understanding-the-generalized-method-of-moments-gmm-a-simple-example/

```
matrix I = I(1)
mat lis I
gmm ((y - exp({xb: percentile_10 percentile_20 percentile_25
percentile_30 percentile_50 percentile_60 percentile_75
percentile_90})) / exp({xb:})), instruments(percentile_10
percentile_20 percentile_25 percentile_30 percentile_50 percentile_60
percentile_75 percentile_90) twostep
```

Here is a first attempt to use GMM, of course I'm missing something.

The answer from Nick Cox was great. I'll try to fit my data with this approach.