An introduction to inverse transform sampling

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Explains how to independently sample from a distribution using inverse transform sampling.
This video is part of a lecture course which closely follows the material covered in the book, "A Student's Guide to Bayesian Statistics", published by Sage, which is available to order on Amazon here: www.amazon.co....
For more information on all things Bayesian, have a look at: ben-lambert.co.... The playlist for the lecture course is here: • A Student's Guide to B...

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12 окт 2024

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Комментарии : 23

@bill0x2a 5 лет назад

You have no idea how long i looked for an explanation of this for an uni assignment thank you so much.

@yamenalharbi2032 2 года назад

Thank you so much Ben. you do not know how much I was looking for this. Great explanation Thanks

@zeitlichkeit540 4 года назад

Thank you so much! Very nice series for Bayesian Statistics! I watch them every day.

@VincentBMathew 4 года назад

What an amazing video.! Never thought I could understand this concept within 11 minutes

@musondakatongo5478 4 года назад

Thanks Ben, you are always great in explaining concepts. I am happy :-)

@yigitokar 6 лет назад

Hello Ben, huge fan here :) Thank you for your videos they are awesome.

@kubawlo 5 лет назад

Why do we have to "go through" the CDF computation to generate a normally distributed variable from a uniformly distributed one? One could have a hunch that since we ultimately want that the resulting variable follows a desired PDE, it seems it should be enough to invert the desired PDE and compute back the variables from uniformly distributed variables. There are some proofs on wikipedia but I can't get any intuition about it. Thanks!

@arpitatripathi 5 лет назад

Thank you so much for this, Ben!

@JibranAbbasi_1 4 года назад

you mentioned that calculating the CDF in higher dimensions is not feasible. Is that because it requires us the calculate the integral?

@SpartacanUsuals 4 года назад

Good question - yep, that’s right; calculating the CDF via integration typically isn’t possible. Best, Ben

@grjesus9979 3 года назад

Then, why is important the uniform pdf?. I mean you could sample directly from one distribution to another just by putting the value returned from the CDF of the first pdf as input to the inverse CDF of pdf you want to arrive at. Am I wrong?

@ujjayantabhaumik3109 4 года назад

Wonderful explanation. Thank you so much :)

@futurisold 2 года назад

I was searching like a mad lad where was this originally published - does anybody know? It's probably Smirnov, but I can't find anything.

@nussiskate3 5 лет назад

great explanation, thanks!

@jayjayf9699 5 лет назад

How come sometimes I see the inverse transformation of an exponential distribution written like X=(-1/lamda)*log(u) ? Am I missing something, I’ve seen it an answer for the actuary CT6 2018 paper question 1, I’m confused please shed some light on it

@c0forerunner0 5 лет назад

Lamda is the rate parameter for an exponential distribution, in Ben's example the rate parameter is one so it kinda just "disappeared", but the PDF of an exponential distribution is -l*e^-lx (l is lamda), and you can verify yourself that the inverse CDF ends up being X=(-1/l)*log(1-u). As for the 1-U vs U, U is a uniform random variable taken from 0-1 so sampling from 0-1 and taking 1 minus a sample from 0 to 1 is the same thing.

@pandabearguy1 2 года назад

(1-u) and u have the same distribution in this case

@tripp8833 Год назад

thanks!

@engineering8896 5 лет назад

Is CDF same as Probability Density Function (PDF)?

@Michel-de4dx 5 лет назад

No the CDF is the integral over the PDF that should equal 1.

@farahbkz.8014 4 года назад

No, as @Michel said. It's the cumulative distribution function.

@longflyer63 6 лет назад

If You want to increment the visits I believe You have to write full your speaked. In this way everyone will translate and understand better with help of a translater 😉 Bye and thanks ☺