As when I get values, I get them in elements, I was thinking on interpolating to nodes using the same technique (angular weights), so hopefully the gradient will match correctly the values
hi people. According to you, which is the best book in numerical analysis of differential equations? I have A. Iserles' book https://www.amazon.com/Numerical-Differential-Equations-Cambridge-Mathematics/dp/0521734908 (I'm a math student really interested in numerical analysis)
hahaha that happened once to me. Head of trimmer broke mid shave and got completely razored chunk. My gf looked at me weirdly for 2 days, as I shaved completelly
I have to find the 6th degree polynomial for the function $f(x)=xe^x$. After which the use of the Chebyshev min-max approach I have to use the list grade polynomial approach with respect to the fault 0.01 at [-1,1].
I don't think that I can use Taylor or Maclaurin.
Any idea? I use only Matlab.
Just testing flawr answer which seems the best. Plus, I may use the same tipe of interpolation for the fucntion values in the nodes, hopefully filling the gap that that dude was telling me about
@biggi_ ▽ for you, and only you. Please do not share
I have no idea what the usual methods are even :/. But I did try some random examples and it gives good/reasonable results
both parabola and plane give quite consistent results, and when I used an image, it gives reasonable directions also. I am going to comment this tomorrow with my supervisor, who is a mathematician, see what comes out of it
Ok well there is a more or less trivial result: Any convex combination of the gradients of neighbouring triangles does converge to the actual gradient (converge in the sens of getting finer and finer meshes)
at least linearly in the triangle diameter (this is similar to the linear convergence of a one sided difference quotient for approximating the derivative)
right: the rought idea is that if we have a C1 function (meaning it is differentiable and it has continuous gradient) and we interpolate linearly
then there is always some point on each triangle where the gradient of the triangle is equal to the gradient of the function
so you probably need to assume that the function is a little bit more than C1 (more regular, e.g. the gradient is lipschitz continuous I think might suffice) then you can say that the smaller you make your triangles, the better the approximation becomes
So.... What we are trying to see is when a polynomial approximation of the function has the error bounded, so we can trust it. But it depends in f, which makes sense.
How does that relate to e.g. that angle weighting you do in the nodes? Or does this only truly proves that the gradient method for the elements can be good
if for some reason our interval is not compact we need another condition: and lipschitz continuity of f^(n+1) is also sufficient to show that f^(n+1) is bounded
the next step is generalizing over not only just one interval but the whole domain we're working in, ususlly just done by maxing over the whole domain instead of one interval
right
in your 2d case we use a (piecewise) linear interpolation of the "actual" function
now we can (probably:) apply a similar theorem as the above in 2d
and say that our linear interpolatin will not be too bad (converge to the actual function)
and similarly that the error in the gradient is also not too bad
and since our gradient is constant within each element
it basically does not matter where within the element we compare the gradient of our interpolation to the true gradient
So, if polynomial interpolate -> there is an upper bound to the error we can have (as long as f^(n+1) is bounded) -> maximum error exist in nodes too -> we are not doing crazy stuff, our approximation is valid for small triangles
For a linear aproxomation (as you did in your post), then f^1 has to be bounded? so The gradient
what is worth noting: these are arguments usually used in the FD-world, the FEM world uses quite a different theory (hilbert (function)-spaces and the lax milgram theorem in short) where you don't think of interpolating single nodes, but you consider a Hilbert space of functions, and for computing you just consider the space of piecewise linear function on your triangulation.
Using finite differences, how u write the jacobian matrix of u(x)*u'(x) ? If I call D the discretization matrix for the first derivative, I find out the expression diag(D*u)+diag(u)*D. It seems good, what do u think?
I discretized the differential equation introducing m equally spaced nodes x_i, in the interval (a,b).
And using finite differences, I get the matrix A and B which applied to a vector u, gives me u'' and u'. The equation becomes: A*u + spdiags(u,0,m,m)*(B*u)=0.
The zero of this equation involving matrices is the solution, and, in order to find it, I have to solve a non-linear system with newton.
So I call F=@(u) Au + spdiags(u)*(Bu), and the dF/du=A + diag(B*u)+diag(u)*B.