Numerical PDE Find the fourth-order, central difference approximation for ux.

FInd the solution of the first-order PDE: X2 ux + xy uy, u = 1 on...

FInd the solution of the first-order PDE: X2 ux + xy uy, u = 1 on x = y2 Determine where the solution becomes singular?

Using the central divided difference approximation with a step size of 0.4, the derivative of f(x)...

Using the central divided difference approximation with a step size of 0.4, the derivative of f(x) = 6x^4 at x = 2.1 is ____. Keep 4 decimal places.

Find the second order Fourier approximation of the function ?(?) = ? on −? ≤ ?...

Find the second order Fourier approximation of the function ?(?) = ? on −? ≤ ? ≤ ?

3) If f=f(x, y), derive a forward finite difference approximation of 3rd order accuracy, O(h³), for...

3) If f=f(x, y), derive a forward finite difference approximation of 3rd order accuracy, O(h³), for ∂f/∂x.

Compute the first-order forward, backward, and central difference approximations to estimate the first derivative of y...

Compute the first-order forward, backward, and central difference approximations to estimate the first derivative of y = x3 +4x−15 at x = 0 with h = 0.25. Compare your results with the analytical solution.

Let u = ⟨1,3⟩ and v = ⟨4,1⟩. (a) Find an exact expression and a numerical...

Let u = ⟨1,3⟩ and v = ⟨4,1⟩. (a) Find an exact expression and a numerical approximation for the angle between u and v. (b) Find both the projection of u onto v and the vector component of u orthogonal to v. (c) Sketch u, v, and the two vectors you found in part (b).

Complete steps (i)-(vii) below in order to estimate the following values using linear approximation: (a) cos(31π/...

Complete steps (i)-(vii) below in order to estimate the following values using linear approximation: (a) cos(31π/ 180) (i) Identify the function, f(x). (ii) Find the nearby value where the function can be easily calculated, x = a. (iii) Find ∆x = dx. (iv) Find the linear approximation, L(x). (v) Compute the approximate value of the expression using the linear approximation. (vi) Compare the approximated value to the value given by your calculator. (vii) Compare dy and ∆y using the value...

find the derivative of cos x at x=1 by first order forward 2nd order and 4th...

find the derivative of cos x at x=1 by first order forward 2nd order and 4th order central schemes with h=0.01

Let f(x,y)=xcos(πy)−ysin(πx)f(x,y)=xcos⁡(πy)−ysin⁡(πx). Find the second-order Taylor approximation for ff at the point (1, 2).

Let f(x,y)=xcos(πy)−ysin(πx)f(x,y)=xcos⁡(πy)−ysin⁡(πx). Find the second-order Taylor approximation for ff at the point (1, 2).

Consider the second order linear partial differential equation a(x, y)uxx + 2b(x, y)uxy + c(x, y)uyy...

Consider the second order linear partial differential equation a(x, y)uxx + 2b(x, y)uxy + c(x, y)uyy + d(x, y)ux + e(x, y)uy + f(x, y)u = 0. (1) a). Show that under a coordinate transformation ξ = ξ(x, y), η = η(x, y) the PDE (1) transforms into the PDE α(ξ, η)uξξ + 2β(ξ, η)uξη + γ(ξ, η)uηη + δ(ξ, η)uξ + (ξ, η)uη + ψ(ξ, η)u = 0, (2) where α(ξ, η) = aξ2 x + 2bξxξy + cξ2...