my dude, just wanted to tell you, that your explanation has just the right amount of amount of theoretical background justification to make all of this stuff reasonable and not just bunch of steps from a "cookbook". awesome stuff!
Thank you, I have a differential equations midterm in a couple of days and I just understood more about this problem with your 7 minutes video than in a couple hours of reading notes and solved exercises
so clear; is very similar that a non-homogeneus ode, in this case your particular solution is the transient term and the homogeneus solucion would be the steady state, not exactly the same, but you can do an analogy
Thank you! I saw a solution to the heat equation where u(0,t) != u_0, and got so confused. It makes sense now that I’ve seen your explanation of how phi(x) settles to the boundary condition when given enough time. Again, many thanks!
I like ur videos and i want to ask something. What i got is, So if we have inhomogeneous BC we can't use separation variables and must to change the BC into homogeneous then we be able to solve with the separation variable. Right? Is there a way to solve the inhomogeneous BC of PDE without change it into homogeneous?
Hi Khan, Thank you so much for this video, it was totally helpful. I would like to ask what happens if the initial condition of the transient solution derived from the given formula turns out to be zero
Could you please tell me how to solve heat equation for one boundary condition is constant temperature and other is variable. For example (two rods joined together in series)
What if the boundary conditions were: a) Derivative at x=0 being some constant u_0 b) Derivative at x=L being some other constant u_L ?? Would there be steady state solutions? If yes, which ones?
Hi Paul, I don't cover Green's functions here, but I'm planning to later, unless you're referring to something I mention in the video, in which case let me know!
Great video! But I have one question: What happen if my B. Conditons are homogeneous, but my PDE, that is the same equation of this video, contains a constant, that i can call "a". In that case, my problem is nonhomogeneous, not by the B. Conditons but by the equation itself. Can i use this method of the sum of a steady and transient solutions?
Would the integrals of the steady state solution have "constants" that a potential functions of t, since it is only the partial derivative wrt X that are zero?
HI ! I would like to solve a non homogenous Boundary conditions heat diffusion problem involving time dependent boundary conditions, so I have to solve transient heat equation with transient boundary conditon. This video let me believe that I can use this steady stade/transient state separation method to solve my problem, is it correct ? My second option is to use Laplace transform with transient condition however I can't find exemple to help me, have you got an idea about how do I have to procede ? Thks by advance. Hugo
I always use this method for all homogeneous separation-of-variables equations; might as well do that since this method is a more general version anyway, and it also gives me lots of review practice.
What can I do when I have nonhomogenous time dependent boundary conditions? In my case I have on the one side du/dx=f1(t) and on the other du/dx=a*u(L,t).
Thank you for the question! I believe I cover more general cases like time-dependent boundary conditions in the next video. Link: ua-cam.com/video/heY4cS1v870/v-deo.html
I guess I´m too late to help you, but you fit the derivative of the stationary solution to those conditions and get the stationary solution integrating
my dude, just wanted to tell you, that your explanation has just the right amount of amount of theoretical background justification to make all of this stuff reasonable and not just bunch of steps from a "cookbook".
awesome stuff!
I LOVE you! I wish you all the best in your academic and personal life. You deserve it for being such an angelic being!
Thank you so much!
Wow! The best PDE series ive seen so far! Great work.
This guy is the king of explanation!
Thank you, I have a differential equations midterm in a couple of days and I just understood more about this problem with your 7 minutes video than in a couple hours of reading notes and solved exercises
this video is super cool. It explains non homogenour bc equation clearly.
so clear; is very similar that a non-homogeneus ode, in this case your particular solution is the transient term and the homogeneus solucion would be the steady state, not exactly the same, but you can do an analogy
Thank you! I saw a solution to the heat equation where u(0,t) != u_0, and got so confused. It makes sense now that I’ve seen your explanation of how phi(x) settles to the boundary condition when given enough time. Again, many thanks!
Bro can you tell me what is inhomogeneous boundary conditions
I like ur videos and i want to ask something.
What i got is, So if we have inhomogeneous BC we can't use separation variables and must to change the BC into homogeneous then we be able to solve with the separation variable. Right?
Is there a way to solve the inhomogeneous BC of PDE without change it into homogeneous?
Excellent dtuff
Hi Khan, Thank you so much for this video, it was totally helpful. I would like to ask what happens if the initial condition of the transient solution derived from the given formula turns out to be zero
Then your solution to the PDE is going to be equal to the steady state solution, since u_tr will just be zero.
@@FacultyofKhan Thank you
Could you please tell me how to solve heat equation for one boundary condition is constant temperature and other is variable. For example (two rods joined together in series)
THANKYOU!1 exactly what i ws looking for!
Hi! I don't understand why can't you use separation of variables with non homogeneus boundary conditions. Thank you.
What if the boundary conditions were:
a) Derivative at x=0 being some constant u_0
b) Derivative at x=L being some other constant u_L ??
Would there be steady state solutions? If yes, which ones?
can you explain the greens functions.?
Hi Paul,
I don't cover Green's functions here, but I'm planning to later, unless you're referring to something I mention in the video, in which case let me know!
Great video! But I have one question: What happen if my B. Conditons are homogeneous, but my PDE, that is the same equation of this video, contains a constant, that i can call "a". In that case, my problem is nonhomogeneous, not by the B. Conditons but by the equation itself. Can i use this method of the sum of a steady and transient solutions?
Would the integrals of the steady state solution have "constants" that a potential functions of t, since it is only the partial derivative wrt X that are zero?
God Bless You
HI ! I would like to solve a non homogenous Boundary conditions heat diffusion problem involving time dependent boundary conditions, so I have to solve transient heat equation with transient boundary conditon. This video let me believe that I can use this steady stade/transient state separation method to solve my problem, is it correct ? My second option is to use Laplace transform with transient condition however I can't find exemple to help me, have you got an idea about how do I have to procede ? Thks by advance.
Hugo
I always use this method for all homogeneous separation-of-variables equations;
might as well do that since this method is a more general version anyway, and it also gives me lots of review practice.
thank you srila prabhupada , krishna and sir
thank you
Thanks a lot!
Are you applying the Method of Eigenfunction Expansion in this video?
Nope not in this one.
What can I do when I have nonhomogenous time dependent boundary conditions? In my case I have on the one side du/dx=f1(t) and on the other du/dx=a*u(L,t).
Thank you for the question! I believe I cover more general cases like time-dependent boundary conditions in the next video. Link: ua-cam.com/video/heY4cS1v870/v-deo.html
What happens if your boundary conditions are derivatives?
I guess I´m too late to help you, but you fit the derivative of the stationary solution to those conditions and get the stationary solution integrating
If this guy tought me calculus in school! Ahhhh
tnx you
imo nonhomogenous is easier. if took such a huge leap to understand homogenous that nohomogenous is just easy
playback speed = 0.25 makes this way easier to follow
yooo he saying uss that means amerikaaaaaaa