I am using the Gauss-Laguerre quadrature to approximate the following integral

First formula

I wrote the function in R


First, I used integrate() function to get the "true" value, which I double check with Wolfram Alpha

integrate(int.gl, lower = 0, upper = Inf)$value
[1] 1.627777

Then, I used glaguerre.quadrature() function

rule<-glaguerre.quadrature.rules(64, alpha = 0, normalized = F)[[64]]
glaguerre.quadrature(int.gl, lower = 0, upper = Inf, rule = rule, weighted = F)
[1] 0.03610346

Clearly, the result is far away from the true value. At that time, I thought I had to transform this function to include a e^(-x) term. So, let X = 1/Y. I obtained a different formula but the same integral

Second formula

In the same manner, I used the following R code

integrate(int.gl2, lower = 0, upper = Inf)$value
[1] 1.627777
glaguerre.quadrature(int.gl2, lower = 0, upper = Inf, rule = rule, weighted = F)
[1] 0.03937068

Well, two different values. Does the Gauss-Laguerre quadrature have trouble in finding this integral? Is there any other Gauss-type quadrature can help find this integral?

Note: I have to use Gauss-type quadrature since I am trying to find MLEs of some parameters for a customized distribution. For simplicity, I just fixed these parameters(these constants in the integral). However, integrate() function seems to be less "robust" than glaguerre.quadrature() function. (integrate() returns divergent error when optimizing the log-likelihood).


According to Hans. W's comment, I check the use of glaguerre.quadrature with the following example. Suppose we wanna find the following integral


glaguerre.quadrature(int.gl3, lower = 0, upper = Inf, rule = rule, weighted = F)
[1] 0.1741448
integrate(int.gl3, lower = 0, upper = Inf)$value
[1] 0.1741448

It seems like the use of glaguerre.quadrature is correct.

Let's check the transformation now. I transform this integral, by letting 100Y=X, such that it includes exp(-x).

integrate(int.gl4, lower = 0, upper = Inf)$value
[1] 1.627777
glaguerre.quadrature(int.gl4, lower = 0, upper = Inf, rule = rule, weighted = F)
[1] 0.9621667

The result is more close to the true value but not exactly equal.


Here is my complete example

Integration and false convergence of optimization in R

  • I assume your use of gaussquad::glaguerre.quadrature is probably and the transformation of the integral is certainly incorrect; e.g. the exponential term must be exp(-x). I tried pracma::gaussLaguerre with the corrected integrand and I failed, too. It seems like this function is converging to zero much too slowly for the in R available Gauss-Laguerre implementations. – Hans W. May 15 '18 at 18:10
  • @HansW. As you mentioned, it was improved but still not that good. – C.C. May 15 '18 at 21:58
  • Your transformed function int.gl4 is now converging rapidly enough to be handled by integrate. Even integrating it over the interval [0, 100] is sufficient for double precision: integrate(int.gl4, 0, 100) will return "1.627777 with absolute error < 2.8e-05". – Hans W. May 16 '18 at 2:09
  • @HansW. For this example, yes, integrate can handle this integral perfectly. However, I intend to use Gauss-type quadrature which, I think, is more robust than integrate because integrate was more likely to returns divergent error when I did optimization to find MLEs. For simplicity, I fixed those parameters. That is the reason why you can see constants in the integral. – C.C. May 16 '18 at 2:35
  • 1
    As long as you do not provide a relevant example, it is difficult to help you. Basically, for integrating a badly converging function with Gauss-Laguerre, you will need many, many more nodes than those 64 you compute here. Saying that a procedure giving wrong results is better than one that is not robust -- that is a bit of a strange consideration in my eyes. – Hans W. May 16 '18 at 8:39

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