Thank you!

Glad you like them!

Happy to help!

You mean N is pointing at the center of curvature, right? 😃

@@bprpcalculusbasics Bang on!! So now break up the acceleration vector, R ' '(t) , into 2 rectangular componenets (not a_x and a_y) : instead, one in the direction of the tangent (a_t) and perpendicular to the tangent (a_n). This normal component point of acceleration, a_n, points right at the Center of Curvature. And if a point mass is moving along the curve, it's the a_n component of the accelaeration that makes it turn, whereas a_t increases or decreases the speed = |vector v|. So cool. Thanks, yet again, for another great video - Newton is smiling.

@@ianfowler9340 yes. I actually just did that video two days ago! And you can probably guess what comes after that! Btw, I am following the calc book by Thomas and I think it’s a fantastic book.

Blind person be like: Why there are so many dt 😂 😂

I hear your frustration. But differentials are defined in such a way so as to force "the operation: [d by dx][of y]" to actually equal "the division: (differential of y)/(diffrerential of x)". That is, to force "dy by dx" to behave like a fraction - at least for mult. and division. There are no restrictions on the size of the diff. of x (or dx) - large or as small as you want, because: dx is defined as delta x and dy is defined as f '(x)*delta x = f '(x)dx. Re-arranging we obtain: "(diff. of y) divided by (diff. of x)" is indeed equal to f ' (x).

It will remain useful for students for years to come.