Probably because one needs a relatively sophisticated math background/education to really follow this stuff, and that is an investment very few people are willing to make. But you're right - no one's stopping anyone from doing so...
@@jonahansen no , lol.. chinese study this in their 10th grades and Indians in their 11th grade , same with most of the other asian countries , its just so basic
@@tanmaymishra9576 wtf no we don't study waves in this depth in 11th in India, wdym?? This is the hardest elective in my college in 1st year. Stop spreading misinformation. And you don't have second order differential equations in JEE advanced either so yeah I can't get from where you are basing this whole argument from
@@Upgradezz Are you asking if there are classes besides those on OCW? If so, as far as I can tell it's only the bigger (edit: in terms of enrollment) classes that have recorded lectures here. Many smaller classes have just lecture notes/assignments, or haven't been added to OCW yet. Here's the catalog for physics stuff: catalog.mit.edu/subjects/8/
At 51:35 when Prof Lee talked about the large ω_d limit, I think tan(δ) is negative and approaches 0 as ω_d goes to infinity (according to the tan(δ) formula obtained earlier in this lecture). Hence δ goes to π as ω_d goes to infinity.
I still can't get why delta goes to π. The limit of that ratio is clearly 0 as ω_d goes to infinity. Why delta is equal to π? Maybe because the solution of tan δ = 0 is δ=0 + k*π. In this case another solution of the equation could be δ=π.
@@lorenzomarchio3694 The tan function exists between closed intervals of 2pi (meaning with verticals asymptotes on both intervals limits). The interval centered on zero goes from minus pi to pi. So lim of tan(x) as x goes to pi is +infinity. That is what he is saying.
If I have a number of glasses, is it possible that I can generate good music from the combination of each glass? How can I simply generate a sound like this 1:07:52 outside the class ? Is this phenomenon 1:13:49 that makes the window glass vibrate when the vehicle passes? At what frequency does our eardrum tear?
there is a error in the calculation of the limit ag 50:00 tan(delta)=Wd/(Wo^2-Wd^2) so, when Wd goes to infinity, tan(delta) goes to Wd/-Wd^2=-0 and tan(delta) goes to pi
The ambience of this class is so much different from some of the other MIT OCW classes. I don't mean the instructor specifically; it has to do with the way the students look disengaged. It reminds me of undergraduate classes I've been in where people were there because of a requirement, not because they cared about the material.
50:00 what the heck is d(t) exactly? Is it some driving force? And why does it equal to Delta( sin ( w_d * t))? I don't see the d(t) is the force diagram. And if d(t) is indeed the driving force, shouldn't it be d0 cos(w_d t) something? It's super confusing here