I have to take another test in my current master's course and I feel clueless. The worst part is not getting any feedback, or answers to questions, from my instructor.
I thought I was paying a lot of money to get an education in a difficult subject, I didn't realize I was going to pay a lot of money just to watch videos and have to figure everything else out on my own (or not figure it out, as the case may be).
Yes, I'm frustrated.
You can use the Gamma function to express fractional factorials.
ReplyDeleteNo, but you've made me curious.
ReplyDeleteWhy does the gamma function have the form it has? How was it created/discovered in the first place, such that it has that form?
ReplyDeleteWhy does a gamma distribution have the form it has?
I get the idea about "fractional factorials" but still can't calculate them. And that doesn't answer the questions above.
I don't want just to memorize a formula. I want to understand what the heck I'm doing.
The gamma function is a result of applying the analytic continuation to a polynomial multiple of the power series of e^z, which gives the n! when evaluated at (n+1). So it was _rigged_ to work out so that Gamma(n)= (n-1)! The analytic continuation is discussed in complex analysis (usually). So I'm not sure the ideas are easily explainable without that.
ReplyDeleteUnfortunately, I never mastered this part of probability, and had to just memorize formulas here.
Truthfully, I don't know the whole history. I can find a couple things that let me make some guesses, though. Start with Wolfram's history information:
ReplyDeletehttp://functions.wolfram.com/GammaBetaErf/Gamma/35/
If you start with the factorial function and try to imagine a continuous version of it, you'd be led to looking at functions which have some special properties. The first is a simple recurrence relationship:
f(x+1)=xf(x)
which the factorial function satisfies, and should be true for any generalization of it. There is only one function which meets all of the desired criteria: this is the gamma function. If you went looking for the work by Bohr and Mollerup you could probably learn what all the criteria are, and how every other function gets eliminated (Wikipedia has a brief summary and some further links to explore- try Bohr Mollerup).
The gamma distribution is, in a sense, a generalization of an exponential distribution. If you have a set of independent variables which have exponential distributions, their sum will have a gamma distribution. This provides some connection to other distributions as well (e.g. Poisson, which is a commonly found experimental distribution in the physical sciences). A cursory glance finds this page:
http://www.quora.com/Statistics-academic-discipline/How-do-Gamma-distributions-arise
which might get you started.
Another site which might be useful (caveat lector: I have not really looked at the applets or the detail).
http://www.math.uah.edu/stat/poisson/
It's pretty frustrating that you have to find these yourself without even a good starting point. I won't try to justify it, but I would suggest that you can make the most of it: learning how to find things out from minimal clues will make you better able to answer far-reaching questions from interested students.
Try the following excellent book on the topic:
ReplyDeleteThe Gamma Function by James Bonnar. It cleared the topic up for me quite nicely.