I like your teaching style. After 40 years as an Engineer, you're the first person who has explained Weibull and how to use it clearly and succinctly.

this is hands down the best explanation i have seen. I am a master's student in materials engineering and we covered this a few days ago. Thank you so much!!

The greatest video about Weibull i have ever seen. Focused on fundamentals!!.

Love you man, Finally found some one who is passionate about explaining this

Your explanation was superb. I plotted my own data as a Weibull plot as I went along with the video.

Taylor, your lecture style is super engaging and very informative. This lecture on Weibull Analysis has me going into my next exam with great confidence!

i would take this professors evvery class. what a positive attitude man

Thank you very much. Really awesome. I'm a experienced engineer and this is the best explanation on Weibull I've seen so far. Tks again.

I am doing a structural analysis using steel, this Weibull distribution is exactly what I am looking for. Thank you, professor.

You saved me, I left all the homework till last minute, but luckily I found this awesome video, well explained thanks so much.

Very cool. While I was at “the U”, Dr. Hoeppner was really big on the Weibull. Glad to see it live on.

what a nice lecture for Weibull distribution. Thank you so much!

This was really good and informative! Thank you so much!

Taylor, that was impressive. Now, I need the 2 variable model.

You are an amazing professor.

very nice way you teach Taylor..!! I will search more videos of yours.

Doing concrete analysis at university now. Trying to understand what exactly I am looking at on this Weibull linear graph and now I do! Thankyou!

Awesome teaching

Great explanation Sir

This is great! Thank you for uploading!

Explained it very nicely.Thank you.

Great teaching!

Thanks, Prof. Using this for some fiber analysis. Hopefully, the manuscript gets accepted.

I loved the explanation .

Thank you Dr. Taylor

Just for records. I was the 1000th user to like this video!

Thank you for the video.

Hi Taylor, I am researching the strength of eggshells for two different diet groups. For the strength values, the Weibull distribution fits both groups very well, and I want to know if there is any statistical difference between these groups. Do you know how could I do this?

how is F=1-exp (-sigma_f/sigma_o)^m the following 1/(1-F)=exp(sigma_f/sigma_o)^m ? please explain steps

Thank you for the informative lecture. Could you also share the link to the Ch.15 Composites lecture as listed in the course outline shown at the right-side?

ok, i came back here to leave this comment because i am stuck on a real-world situation. I have 25 samples of 3d printed parts i tested in the tensile machine. The maximum was about 55MPa for PLA+ and the low was around 46MPa. I have used the same rank formula as you, as well as the median rank method. I have found the slope (beta) also known as the shape parameter, but now i am trying to find the scale parameter known as n. The scale parameter (characteristic life), representing the time at which 63.2% of items are expected to fail. This value should be in the range of all my tensile strengths. when plotting the data in excel and getting a line, i have y=27.26x-86.048, if i do e^-86.048 to get n, its a HUGE number. so i have messed up somewhere haha. below are my tensile values i tried to use chatgpt but got some serious random errors. I am a mechanical engineer working on my masters but none of my classes went over this haha I am trying to use the cumulative distribution function (CDF) but it requires beta and n. CDF=1−e^-(t/n)^b any help would be excellent. Maybe chatgpt confused 46.1 46.7 47.3 47.9 48.3 48.6 49 49.2 49.8 50.1 50.4 50.7 50.9 51.5 51.8 52.1 52.5 52.8 53.1 53.2 53.9 54.4 54.6 55.2 55.6

Thanks for this great explanation. I'm confused about ln(ln(1/(1-F)) vs F. If I want to have a 1/1,000,000 chance of failure, I find the log(stress) value corresponding to the F = 1/1,000,000 along the data trendline. I don't use ln(ln(1/(1-F)) for that, right?

Great explanation. Do you have any thoughts/videos on utilizing Arrhenius equation to predict material property?

Simply great!

Hello Taylor, thank you for sharing these useful insights. I am wondering how we can determine the Potential Failure using the weibull analysis, or how can we plot the P-F curve using weibull

This is the clearest explanation I've seen so far. It is unintuitive for me on how the failure rate is based on a rank and not a bucket, or histogram that counts failures. I'm going to have to spend some time looking into that. Any book or source you recommend for learning about F?

Is there anywhere where F = (n - 0 5)/N is cited as the go-to for rank approximation?

39:34 what does the “m” represent in the legend of the confidence interval vs sample size plot?

I'm currently designing a cost model for solar power plant, in which I should define the "average failure rate" of devices over its lifetime....how can I benefit from the Weibull distribution .....thank you.

For the x-axis how do you resolve it when given bending strength instead?

Thanks for the tutorial! I have one question regarding how you calculate F (in your case F = n-0.5/N). I have encountered other approximations for F like F = n-0.3/N+0.4 (mean rank approximation) or F = n/N+1. When is it more appropriate to use one or the other? Is there a relationship to the sample size? Thanks!

What is the formal name for the scaling equation introduced at 43:50?

Thank you for this video!

One question, can anyone explain how the calculations are performed at 33:00? Otherwise, this is the first video that ever made sense to me. I've been trying to understand this for at least a year.

Superb! One question though. Can you explain the equation F=1/1e^6?

Hi Taylor! Fantastic explanation!! Thank you...My question is: the Length of failure in your excel spreadsheet it CAN BE MTBF??? Can I calculate reliability as you have done using the MTBF?

Do you have anything on log normal distributions?

Mind blown!!

When you ranked them, some of them have the same length (16th and 17th), so it should be the same rank otherwise it gives different failure rate for the same length ?

Any limitations of Weibull distribution? considering that we consider the data distribution to be linear. Also, can we use this Weibull distribution for the particle size distribution. Video was awesome!!!

Thank you for this video, please I have a question, how do we estimate the failure function, if I have the number of data exactly 20

Thanks for the great lecture. I'm confused on the intuition behind length of elongation of the component computation. Is it akin to the idea of that: we have 100 bars so we must calculate at least 1 failing and hence this is like changing the required 1 / 1 million to 1 / 100 million in the original equation?

Thank you sir for this video. Can you please help me out for plotting weibull curves in excel based on service life prediction of building data. Plotting of Condition index vs.Time in years

Thanks

wHY DO WE PLOT LN(LN (1/1-F(X)) ) ON X AXIS TO GET THE SLOPE AND INTERCEPT

20:10 the ranking :: what if we left the data is it comes, in other words, without reranking it, let the first sample rank to be first, second be second and so on

Can I use this method for wind loads that don't give a specific direction?

If i wanted to learn more about using excel in this way and this type of statistics, what would i take? thanks. I am graduating this month in mechanical at UVU but even in my undergrad, we hardly touched on this stuff, even at SLCC I actually learned more stats in my black belt independent study i did through an online company than i did my schools haha

Is there a link to the files used in the video?

How to use Weibull formula for precipitation in hydrology?

Great

@29:35 why the F for the one in a million is 1/e^6. My feel is that it should be 1/10^6.

at 30:00 you calculated F to be 1/1e^6.....shouldn't F= 1/2e^6 because of the formula F= (n-0.5)/N which equal to 0.5/1e^6 or as 1/2e^6

pika pika !

The length at failure, has nothing to do with the failure rate.