Thank you very much, Mukta!

Yes. Same here. I'm a teacher too and you described this really well. Thanks!!

Thank you!

I'm happy to hear that! You are very welcome.

Hello Rhonda and Mukta! I'm a student studying at the Bsc level. Is there any youtube channel that you guys would suggest to learn partial differential equations that explains the concepts very well like this? I learned about ODE from Khan Academy but it doesn't have PDEs. Please help!

Thank you so much! I'm glad this was helpful.

+petergianf Thank YOU!

Thanks so much, Dan!

That is very kind, Yaman. Thank you!

You're welcome!

Thank you very much!

Thank you, Jacob. Good luck with your studies!

Thank you!

Thank you!

hey please maKe more videos

+Ander Stuhl Katya is nice!

Thank you!

Thank you very much! Your last question is one we all try to answer. It's a great mystery.

+PHaitiano Thank you so much!

+Muhammad Zeeshan Khan You're welcome!

Thank you!

Thank you so much!

Thank you!

Thank you so much!

That's correct. Just trying to keep it simple, but thank you!

the partial derivative slopes are in the so called tangent plane but their vectors are in x and y dir... so the resultant vector(sum of partial derivative vectors=gradient vector) will lie in the x-y plane and the gradient(slope) will lie in the so called tangent plane....please correct me if i am wrong....

I don't fully understand. If the gradient is (2,1). I need to go 2 in the x direction and 1 in the y direction. Therefore do I need to imagine there's an other coordinate system on the tangent surface?

I have a different opinion. I think the Gradient vector is actually in the x-y plane. First, It makes no sense to find a given Gradient vector, like grad f= xi+yj, in the plane tangent to the surface, doesn't it? There are twofold. First, the definition of Gradient is in x-y plane. Second, we haven not define a 2-D coordinate in the tangent plane. Apparently we cannot locate any vector before defining the coordinates, can we? Secondly, note that while Katya is skiing in the 3D space, it actually only needs two 2 variables , x and y, to determine her 3D projectile. This is simply because the 3rd value, z is determined by z=f(x,y). Therefore, when she decides to enjoy the max rate of descent, she only needs a 2-variable vector in her level plane, the -negative Gradient vector. The slope of Katya's actual projectile: is the Directional Derivative wrt a unit vector of the Gradient vector in xy plane. Mathematically, it equals to the |grad f|. So, even you find the vector tangent to the actual projectile, its projection onto the xy plane would not be the Gradient vector. It will be shorter than the Gradient vector. I hope this makes a little bit more sense.

Thank you!!

Thank you, Lorenzo!

Thank you! You, as well.

Thank you!

This may help, Rhonda ;-) kzbin.info/www/bejne/q56bammLqKt-Y8k

Thank you!

Thanks for trying!

Thank you so much!

+Engineerated I'll do my best! Thank you.

Thank you!

Good to hear! Thank you.

+Jawaid Rezai I appreciate that!

Thanks for your thoughtful comments. If you take an example, say f(x,y)=x^2+y^2 and calculate the gradient at a point, say (1,1), you'll see that the gradient vector is a 2D-vector. If you move along the gradient in the xy-plane, the curve traced on the surface will take you in the direction of greatest ascent. The gradient will naturally point in the right direction. If you changed to the function f(x,y)=-x^2-y^2 and again calculate the gradient at (1,1),and do the same thing, you will move along a curve in the direction of greatest ascent. I think you may be confusing 2D and 3D gradients. The gradient in this case is not pointing up or down, it lies in the xy-plane. Hope that helps.

@@rhondahughes9648 Yes thank you very much, I studied your example and better see it is actually doing that. I'm just missing the geometric intuition of why, when we calculate this rate of change, it "naturally" points towards the ascent. To be clearer and very simple, if I calculate the gradient of x², I get 2x and I totally agree that when plugging a value in it, I will go where the function increases the most. I just don't see why it makes sens, why it's not the other way (decreasing) because when I calculate this rate of change, I can approach my point from the left or the right, and a rate of change indicates how much a thing changes but not necessarily in which direction. Anyway thank you very much, I still learned and visualized maany things thaanks to your videos, great work ! Best regards

Thank you so much! You motivate me to do more:)

Agreed!

Gradient is a vector in space and we are here working with 2D space (x and y directions), while z is corresponding to values of function f(x,y), not third dimension of space. So, gradient gives you direction in which function changes the most, but to get there you must move in 2D space, i.e. in x and y directions and function will assume a value depending on the point in 2D space you are at. Therefore, "skiing down the function slope" story was unfortunate. In 3D space, it would look like w = f(x, y, z), where f can for example be a function that maps a temperature to all points in 3D space. In that case gradient would be a 3D vector, and function graph would be 4D. And if you instead use gravitational potential energy as a function od x, y, and z, you can start talking about skiing down the slope. Also, note that if you apply the gradient definition given here to 1D situation, i.e. y=f(x), the gradient _is_ a 1D vector parallel to x axis, and its length and direction define slope of the tangent at a given point, not the tangent itself.

I generally agree with this response, but don't think I say "skiing down the function slope" anywhere in the video. It's very clear that the gradient is the direction in 2D, and the rate of change along the curve is greatest in that 2D direction. That was the main point of the explanation:)

Please bear with me, mathematics is just a hobby of mine, I have no real qualifications in the subject. I do however find what I consider ambiguity in certain mathematical definitions leading to confusion.....at least on my part. I fully understand that the " gradient " is the magnitude of the sum of the two partial derivatives and it's direction is in the x, y plane. But as I understand it, the magnitude of the gradient is a real slope in R3 , however its direction is represented by a vector in R2. I mean if I am on a hill and it slopes one way East and one way West then the gradient gives me the maximum or minimum value of the slope of that hill in the correct direction in R2. depending on whether I wish to ascend the or descend. Why can't the actual slope in R3 be represented by a tangent vector whose tail is at the point of tangency and has a slope equal to the magnitude of the tangent vector. I mean I have to climb up the hill , not into it !Another definition I find confusing concerns the surface integral where it is used as a density function to calculate the mass of an infinitely thin surface........how can a surface that is infinitely thin have a mass? Is this a lack of comprehension on my part, or just poorly defined concepts? Once again any clarification would be gratefully received .

I'm so sorry for the delay in responding. I will think about your question, and respond soon.

Correct!

Thank you! Eventually there will be more:)

You are welcome.

Thank you!

You are absolutely correct! Thank you!