Part A 5 Shorter Problems, 8 points each.

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Math 241 Final Exam Jerry L. Kazdan May 11, 2015 12:00 2:00 Directions This exam has two parts. Part A has 5 shorter question (8 points each so total 40 points), Part B has 5 traditional problems (15 points each, so total is 75 points). Maximum score is thus 40+75 = 115 points. Closed book, no calculators or computers but you may use one 3 5 card with notes on both sides. Please remember to silence your cellphone before the exam and keep it out of sight for the duration of the test period. This exam begins promptly at 12:00 and ends at 2:00; anyone who continues working after time is called may be denied the right to submit his or her exam or may be subject to other grading penalties. Please indicate what work you wish to be graded and what is scratch. Clarity and neatness count. Part A 5 Shorter Problems, 8 points each. A 1. Find a function u(x,t) that satisfies u t u = 7x with u(x,0) = 0. Solution: A particular solution of the inhomogeneous equation is u p = 7x. The general solution of the homogeneous equation is u 0 = k(x)e t for any function k(x). Thus the general solution of the inhomogeneous equation is To satisfy the initial condition we need so k(x) = 7x and u(x,t) = 7xe t 7x. u(x,t) = k(x)e t 7x. 0 = u(x,0) = k(x) 7x A 2. Let R 2 be a bounded region with boundary. Say u(x,y,t) is a solution of u t = u+2u+e t sin(x+2y) in with u(x,y,t) = 0 on and u(x,y,0) = 0; and v(x,y,t) is a solution of v t = v +2v in with v(x,y,t) = x 2 y on and v(x,y,0) = cos(2x). Find a function w(x,y,t) that satisfies w t = w +2w +3e t sin(x+2y) in with w(x,y,t) = 5x 2 y on and w(x,y,0) = 5cos(2x). [Your solution should give a formula for w in terms of u and v]. Solution: By linearity, w(x,y,t) = 3u(x,y,t)+5v(x,y,t). 1

A 3. Say u(x,t) is a solution of the wave equation u tt = 9u xx for all < x <, with u(x,0) = f(x) and u t (x,0) = g(x). Find all the points on the x-axis that can influence the solution at x = 2, t = 4. Solution: The d Alembert formula gives u(x,t) = 1 2 [f(x+3t)+f(x 3t)]+ 1 2 3 x+3t x 3t g(s) ds. Letting x = 2 and t = 4 we find that the only points on the x-axis that can influence the solution are in the interval 10 x 14. A 4. Let u(x,t) be a solution of u t = u xx +au where a is a constant. Show that by making a change of variable u(x,t) = ϕ(t)v(x,t), for an astute choice of ϕ(t) the function v satisfies the simpler heat equation v t = v xx. Solution: By a computation, u t = ϕv t +ϕ t v so u t = u xx +au becomes that is ϕv t +ϕ t v = ϕv xx +aϕv, ϕv t = ϕv xx +[ ϕ t +aϕ]v. To kill the last term, just let ϕ(t) = e at. This idea also works if a is a function of t, in which case let ϕ(t) = e a(t)dt. A 5. Suppose u(x, y) satisfies the Laplace equation u = 0 on the square 0 < x < 1, 0 < y < 1 and has boundary values +1 on the top and bottom (y = 0,1) and boundary values 1 on the left and right (x = 0,1). What is the value of u at the point ( 1 3, 1 3 )? [Hint: What happens to the PDE and boundary conditions if the square is reflected about the line y = x? Say v(x,y) is the solution of the reflected problem. How are u and v related? What can you say about the sum of u and its reflection, v?] Solution: Here v(x,y) = u(y,x) Then v xx +v yy = u yy +u xx = 0 so v also satisfies the Laplace equation. Let w(x,y) = u(x,y) + v(x,y). Then w satisfies the Laplace equation and is zero on the boundary. Thus w(x, y) = 0 throughout the square. Consequently, u(y,x) = u(x,y) so on the diagonal u(x,x) = 0 for all x in 0 < x < 1 (u is discontinuous at the corners of the square). 2

Part B 5 standard problems (15 points each, so 75 points) B 1. Suppose f(x) = { 1 for π x 0 1 for 0 < x π. a) Compute the Fourier series of f(x) for the interval π x π. Solution: The Fourier series is where a 0 = 1 2π π f(x) a 0 + πf(x)dx, a k = 1 π 0 [a k coskx+b k sinkx], (1) k=1 π πf(x)coskxdx, b k = 1 π Because f is odd, the a k = 0. Also, b k = 2 π sinkxdx = 2 π kπ coskx Thus, f(x) 4 π π 0 = π π { 0 k even 4 kπ k odd [ sinx+ sin3x + sin5x + sin7x ] +. 3 5 7 f(x)sinkxdx. b) Draw a graph of the Fourier series (computed above) for 2π x 2π and put an X at all points of discontinuity. Solution: https://upload.wikimedia.org/wikipedia/commons/thumb/2/2c/fourier_series.svg/ There are jump discontinuities at x = kπ, k = 0,±1,±2,... B 2. Let be the unit disk in the plane R 2 and note that it is contained in the square with vertices at ( 1. 1), (1, 1), (1, 1), and ( 1, 1). Let v 1 = λ 1 v 1, where λ 1 is the lowest eigenvalue of the Laplacian in and v 1 (x,y) is the corresponding eigenfunction with v 1 (x,y) = 0 on. Find a number m > 0 so that λ 1 > m. Solution: From the Rayleigh-Ritz quotient, if λ 1 () is the lowest eigenvalue of the Laplacian with zero Dirichlet boundary condition and if +, then λ 1 ( + ) < λ 1 (). Apply this where + is the square with corners at (±1,±1) and (±1, 1). Recall (or compute!) that for a rectangle in the plane with sides a and b then the eigenvalues of the Laplacian are λ k,l = ( ) kπ 2 + a ( ) lπ 2, l = 1,2,3,... b so for our square (a = b = 2), λ 1 () > λ 1 ( + ) = 2 π2 4. 3

B 3. Let T be the triangle 0 x 1, and 0 y x. You may use without proof that the Dirichlet eigenfunctions of the Laplacian on T are given by v nk (x,y) = sinnπxsinkπy sinkπxsinnπy, k = 2,3,... and n = 1,2,...,k 1. (2) and that these eigenfunctions are orthogonal and satisfy v nk 2 da = 1 4 T Use this to write down a formula for the general series solution of the wave equation u tt = u in the triangle T with u = 0 on the boundary, T. As part of this, include the formulas you would use to find the coefficients in the above series in terms of the initial position and velocity. Solution: Using separation of variables, seek the special solutions u(x, y, t) = v(x,y)t(t). Then T(t)+λT(t) = 0 and v +λv = 0, where λ is a constant and v(x,y) = 0 on the boundary, T. By the Raleigh-Ritz quotient, λ > 0. Using the explicit formulas (2) we find λ nk = (n 2 +k 2 )π 2. Then the general solution of the wave equation in T is ( k 1 [ u(x,y,t) = A kn cos λ kn t+b kn sin ) ] λ kn t v kn (x,y). k=2 n=1 (3) Note that u(x,y,0) = ( k 1 k=2 n=1 ) A kn v kn (x,y) and u t (x,y,0) = ( k 1 k=2 n=1 ) B kn λkn v kn (x,y) Because the v kn are orthogonal with normalization (3), the coefficients are determined by the formulas A kn = 4 u(x,y,0), v kn and B kn λkn = 4 u t (x,y,0), v kn. B 4. Let R 3 be a bounded region and let u(x,y,z,t) be a solution of u tt u+u = 0 in with u = 0 on. Define the Energy E(t) by E(t) = 1 [ 2 u 2 t + u 2 +u 2] dvol. 4

a) Show that E(t) is a constant. Solution: de dt = [u t u tt + u u t +uu t ] dvol. By Green s theorem, since u = 0 on, then u u t dvol = u t udvol. Therefore de dt = u t [u tt u+u]dvol = 0. so E(t) is a constant. b) Use this to obtain a uniqueness result for the solution of this equation with specified initial position, u(x,y,z,0), and velocity, u t (x,y,z,0). Solution: Say u and v are both solutions of this partial differential equation in with the same initial conditions u(x,y,z,0) = v(x,y,z,0) and u t (x,y,z,0) = v t (x,y,z,0) and also u = v on the boundary. Let w = u v. Then w satisfies w tt w+w = 0 in, w(x,y,z,0) = 0, w t (x,y,z,0) and w = 0 on. By part a), the energy, E(t), associated with w is a constant. Using the initial conditions, this constant is zero. Because E(t) is a sum of non-negative terms, w(x,y,z,t) = 0. Consequently u = v. B 5. a) In the square 0 x a, 0 y a in the plane, a substance is diffusing whose molecules multiply at a rate proportional to the concentration. It thus satisfies u t = u+γu, (4) where γ is a constant. Assume that u = 0 on all four sides of the square. What is the condition on γ so that the concentration u(x,y,t) 0 as t? b) Generalize part a) to a bounded region in R 2 with boundary condition u = 0 on. Your solution should relate γ to the Dirichlet eigenvalues of the Laplacian. Solution: We work immediately in a general bounded region and use separation of variables, seeking special solutions of equation (4) in the form u(x,y,t) = v(x,y)t(t) where v(x,y) = 0 on the boundary,. Then T(t) T γ = v v = λ, where, using the Rayleigh quotient, λ > 0. As usual, T +(λ γ)t = 0 and v +λv = 0. 5

The functions v(x,y) = v n (x,y) are the eigenfunctions of the Laplacian in with boundary condition v n = 0 on. The corresponding eigenvalues are λ n > 0. For all of the solutions of T+(λ n γ)t = 0 to decay as t we need that λ n γ > 0, that is, γ < λ 1. In the particular case where is a square with sides a this means γ < 2(π/a) 2. Then the general solution of equation (4)is u(x,y,t) = A n e λ n γt v n (x,y) n=1 wherethecoefficientsa n areusuallydeterminedfromtheinitialcondition,u(x,y,0). Remark: Problem A-4 (above) gives another approach to this. 6

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