5). Let V be the space of meromorphic functions on the extended complex plane Ĉ that possibly have poles at 0, 1 and ∞ with orders up to 2. Find a basis for V.

(p). Assume that u(z) is a real harmonic function defined on the disc D(zo, p) = {lz- zolp}. Use Cauchy's integral formula to prove the mean value property: -S u(zo) = [ 2π u(zo + reio) do 27T =

6. [10] Evaluate (2 (2+2y) ds where C is the upper half-circle centered at the origin connecting the point (2,0) to the point (-2,0). 7. [10] Show that the vector field F(x, y, z) = is conservative and integrate it along the curve П C(t) = si sin t, nt, cost,t), te [0,1] 8. [10] Use Stokes' Theorem to compute the integral curl F.dS, where F(x, y, z) = xzi+yxj+xy k I cur and S is the part of the sphere x² + y²+z² = 9 that lies inside the cylinder x2 + y² above the xy-plane. 9. [10] Use Green's theorem to evaluate So √1+x3 dx+2xy dy where C is the triangle with vertices (0,0), (1, 0) and (1, 3). 10. [10] Evaluate the surface integral (x²z + y²z) dS where S is the hemisphere x² + y²+2² = 4, z> 0. = 1 and ☐

Part 1: A linear electrical load draws 1₁ A at a 0.72 lagging power factor. See the table to find ½ for your student ID. When a capacitor is connected, the line current dropped to 122 A and the power factor improved to 0.98 lagging. Supply frequency is 50 Hz. a. Let the current drawn from the source before and after introduction of the capacitor be 1₁ and I₂ respectively. Take the source voltage as the reference and express 11 and 12 as vector quantities in polar form. b. Obtain the capacitor current, Ic = 12 − I₁, graphically as well as using complex number manipulation. Compare the results. c. Express the waveforms of the source current before (į (t)) and after (i2(t)) introduction of the capacitor in the form Im sin(2лft + 0). Hand sketch them on the same graph. Clearly label your plots. d. Analytically solve i̟2(t) − i₁ (t) using the theories of trigonometry to obtain the capacitor current in the form, ic(t) = Icm sin(2πft + 0c). Compare the result with the result in Part b.

Go to page 82 for the geometry problem. Use the formula for the area of a triangle to compute the area given the base and height. Link: [https://drive.google.com/file/d/1RQ2OZK-LSxp RyejKEMg 1t2q15dbpVLCS/view? usp=sharing] Provide a step-by-step solution.

Refer to page 79 of the shared document for the algebra problem. Use basic algebraic rules to simplify the given expression. Link: [https://drive.google.com/file/d/1RQ2OZK-LSxp RyejKEMg1t2q15dbpVLCS/view? usp=sharing] Provide all steps clearly.

Please calculate the shaded area

3. Solve the Heat Equation with Initial and Boundary Conditions Turn to page 71 for the heat equation problem. Solve the partial differential equation using Fourier series or another suitable method, given the initial and boundary conditions. Link: [https://drive.google.com/file/d/1RQ2OZK-LSxpRyejKEMg1t2q15dbpVLCS/view? usp=sharing] Provide all derivations and intermediate steps.

2. Classify the Stability of Fixed Points in a Dynamical System The dynamical system problem is located on page 60 of the file. Identify the fixed points and classify their stability using linearization and eigenvalues. Link: [https://drive.google.com/file/d/1RQ2OZk-LSxpRyejKEMg1t2q15dbpVLCS/view? usp=sharing] Provide a detailed explanation of your analysis.