I am trying to do something in Stata or R.

I have percentiles of a wage distribution (percentiles 10, 25, 50, 75, 90) and I want to estimate a lognormal distribution to fit them. In Stata there is a command lognfit that fits a lognormal to unit record data, but not to percentile points.

Is it worth using Stata's gmm command, using my five datapoints to estimate the two parameters of the lognormal as an overidentified system?

  • Why do you mention R when this seems to be a Stata question? – lebelinoz Oct 10 '17 at 20:46
  • R tag restored. – Nick Cox Oct 12 '17 at 6:39

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.

Here is a Stata solution.

I leave to others the attractions of gmm. You could also regress the logged quantiles on the corresponding quantiles of a standard normal distribution. Here is code embedded in an experiment to see how well the method works. We generate 1000 samples each of size 1000 from a lognormal which is a normal with mean 1 and SD 2 exponentiated. Here it is rangestat that does all the regressions, one for each sample.

clear 
set obs 1000000
set seed 1066 
set scheme s1color 

gen y = exp(rnormal(1, 2)) 
egen sample = seq(), block(1000) 
collapse (p10) y10=y (p25) y25=y (p50) y50=y (p75) y75=y (p90) y90=y, by(sample)  

reshape long y, i(sample) j(p) 
gen pred = invnormal(p/100)
gen log_y = log(y)

* must install from SSC using: ssc install rangestat
rangestat (reg) log_y pred, interval(sample 0 0) 

qnorm b_cons if p==10, name(G1) yli(1) ytitle("") subtitle(mean known to be 1) yla(, ang(h)) 
qnorm b_pred if p==10, name(G2) yli(2) ytitle("") subtitle(SD known to be 2) yla(, ang(h)) 

graph combine G1 G2

enter image description here

  • Thank you all for their answers I appreciate since I'm new in this forum. – Enrique de la Rosa Oct 11 '17 at 22:21

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