Taking numerical analysis right now, our prof doesn't explain things clearly nor intuitively, your channel is single handedly carrying me through the course lol, thank you so much and i wish you the best
Hi! Very in-depth, good video. I enjoyed it and you take it one step at a time. One thing to point out, though, is that at around 4:32 when you're setting up the 3rd equation, you're saying that "y_2 = A(y_2)^2 + B(y_2) + C" when it instead should have been "y_2 = A(\delta(x))^2 + B(\delta(x)) + C. Furthermore, at 4:43, you say to add together equation (1) and equation (2), though that's not what you write on the blackboard. What you write is equation (1) and equation (3) added together. Either way just wanted to give some feedback, but it is definitely a good, clear, concise, and easy-to-follow video, so thank you for that! It helped me a ton with my School Project
@@autismspeakz Yeah exactly! I get that, totally. That’s why I thought it would help others if I added this comment so they don’t think “hmm… did I miss something?”
Thanks for this,i was totally confused. I understood that he made a mistake in the first addition but it was difficult since he wrote the third equation in terms of y instead of delta x. I appreciate your observation. He is such a good teacher
So grateful to have this quality content available. This autumn, I am taking a course in numerical methods, and you're adding a great supplement for a recap at home after each chapter is reviewed by my professor. Not to mention the references for use in assignments at a later time.
Thank you, Professor, for this clear and comprehensive explanation of the smallest details. Can you mention the source you relied on to derive Simpson's 1/3 rule.
Taking numerical analysis right now, our prof doesn't explain things clearly nor intuitively, your channel is single handedly carrying me through the course lol, thank you so much and i wish you the best
Hi! Very in-depth, good video. I enjoyed it and you take it one step at a time. One thing to point out, though, is that at around 4:32 when you're setting up the 3rd equation, you're saying that "y_2 = A(y_2)^2 + B(y_2) + C" when it instead should have been "y_2 = A(\delta(x))^2 + B(\delta(x)) + C.
Furthermore, at 4:43, you say to add together equation (1) and equation (2), though that's not what you write on the blackboard. What you write is equation (1) and equation (3) added together. Either way just wanted to give some feedback, but it is definitely a good, clear, concise, and easy-to-follow video, so thank you for that! It helped me a ton with my School Project
yeah sometimes when that happens instead of saying the video is wrong i start doubting myself if i even know it or not
@@autismspeakz Yeah exactly! I get that, totally. That’s why I thought it would help others if I added this comment so they don’t think “hmm… did I miss something?”
Thanks for this,i was totally confused. I understood that he made a mistake in the first addition but it was difficult since he wrote the third equation in terms of y instead of delta x. I appreciate your observation. He is such a good teacher
So grateful to have this quality content available. This autumn, I am taking a course in numerical methods, and you're adding a great supplement for a recap at home after each chapter is reviewed by my professor. Not to mention the references for use in assignments at a later time.
Thanks! Very useful
Thank you, Professor, for this clear and comprehensive explanation of the smallest details. Can you mention the source you relied on to derive Simpson's 1/3 rule.
what software do you use, plz 🙏🏻
Nice explanation..very useful
Your contents are marvelous!! KEEP IT UP
Amazing, thank you ❤
Welldone
marvellous
Welldone