Can someone do this in Wolfram Mathematica? This is already the interpolation function. I need help please

Let p=0.54617 and q=0.54601. Use four-digit to express p−q.   Find the relative error of the previous part.  If α and β are the roots of an equation, illustrate with an example howloss of significance can be avoided if two numbers are very close to each other.

Consider the linear system with b = (-1,7, -7) and 1 +(239) A = -1 -1 1 -1 (a) Verify that the SOR method with value w = 1.25 of the relaxation parameter converges for this system. (b) Compute the first iteration by the SOR method starting at the point x = (You can do it by hand or wiritng a MATLAB code.) (0, 0, 0).

Use the Gauss-Siedel method to approximate the solution of the following system of linear equations. (Hint: you can stop iteration when you get very close results in three decimal places.) 5x1 - 2x2 + 3x3 = -1 %3D -3x1 + 9x2 + x3 = 2 2x1- X2-7x3 = 3

If you indicate the exact real root of the nonlinear formula f（x ）=x³+2x-5 to four decimal points, calculate each approximation 0, 1, 2, 3, 4 using the secant method in the interval [1,2]. All results are marked up to four decisces. thank you

Consider a gas in a piston-cylinder device in which the temperature is held constant. As the volume of the device was changed, the pressure was mecas- ured. The volume and pressure values are reported in the following table: Volume, m Pressure, kPa, when I= 300 K 2494 1247 831 4 623 5 499 416 (a) Usc lincar interpolation to estimate the pressure when the volume is 3.8 m. (b) Usc cubic splinc interpolation to cstimate the pressure when the vol- ume is 3.8 m. (c) Usc lincar interpolation to cstimate the volume if the pressure is meas- ured to be 1000 kPa. (d) Usc cubic splinc interpolation to cstimate the volume if the pressure is mcasured to be 1000 kPa. 4.

1] Minimize the following boolean function- F(A, B, C, D) = Σm(0, 1, 3, 5, 7, 8, 9, 11, 13, 15)

Using MATLAB, develop a computer program for the finite difference solution with general θ scheme for the 1D consolidation of a uniform layer of soil. Compare the results for θ=0, 0.5, 2/3 and 1.0 for α=0.49 and α=0.51 against the analytical solution of Terzaghi’s equation for T=0.5. Apply the program to both cases of double draining layer and single draining layer.

Verify that the given differential equation is not exact. (x² + 2xy - y²) dx + (y² + 2xy = x²) dy = 0 - If the given DE is written in the form M(x, y) dx + N(x, y) dy = 0, one has My = = 2x-2y Way to go! Nx = 2y-2x Since My and Nx are not equal, the equation is not exact. -2 Multiply the given differential equation by the integrating factor µ(x, y) = (x + y)¯² and verify that the new equation is exact. If the new DE is written in the form M(x, y) dx + N(x, y) dy = 0, one has -4xy 3 Perfect! My = (x + y)³ -4xy NX = (x+y)3 Since My and Nx are - equal, the equation is exact. af (x² + 2xy + y² − 2y²). Integrate this partial derivative with respect to x, letting h(y) be an unknown function in y. Let = дх (x + y)² f(x, y) = Find the derivative of h(y). h' (y) = Solve. | x² + y² − c ( x + y) = 0 + h(y) Impressive work.