MATH 551 HOMEWORK II SOLUTIONS. Graded problems: 1,3,4,6,7. Solutions to ungraded problems abridged. Let D d

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1 MATH 551 HOMEWORK II SOLUTIONS Graded problems: 1,3,4,6,7. Solutions to ungraded problems abridged. Let D d dx and xf, gy ş b fpxqgpxqdx. Integration by parts is then expressed as a xdf, gy fg b a xf, Dgy. 1. Problem 1 (a) We have the following operator and domain. L D 2 3yp0q ` y 1 p0q 0 S yp1q ` 2y 1 p1q 0 We compute the adjoint. xly, vy xd 2 y, vy y 1 v 1 0 xdy, Dvy ry 1 v yv 1 s 1 0 ` xy, D 2 vy Since L L, L is formally self adjoint. The boundary conditions are 0 ry 1 p1qvp1q yp1qv 1 p1qs ry 1 p0qvp0q yp0qv 1 p0qs rvp1q ` 2v 1 p1qsy 1 p1q ` r3vp0q ` v 1 p0qsyp0q The domain of the adjoint is then vp1q ` 2v S 1 p1q 0 3vp0q ` v 1 p0q 0 Since S S, we have that L is self adjoint. (b) We have the following operator and domain $ & yp0q 7y 1 p0q 0 L D 3 ` D 2 D S yp1q 0 % y 1 p1q 4y 2 p1q 0 We compute the adjoint of the summands, citing Part (a) for D 2. xdy, vy yv 1 0 xy, Dvy yv 1 0 ` xy, Dvy To compute the adjoint of D 3 we use the first steps of Part (a): xd 3 y, vy ry 2 v y 1 v 1 s 1 0 ` xdy, D 2 vy ry 2 v y 1 v 1 ` yv 2 s 1 0 ` xy, D 3 vy 1

2 2 MATH 551 HOMEWORK II SOLUTIONS Combining these yields xly, vy xpd 3 ` D 2 Dqy, vy xd 3 y, vy ` xd 2 y, vy xdy, vy ry 2 v y 1 v 1 ` yv 2 ` y 1 v yv 1 yvs 1 0 xy, D 3 vy ` xy, D 2 vy ` xy, Dvy ry 2 v y 1 v 1 ` yv 2 ` y 1 v yv 1 yvs 1 0 ` xy, p D 3 ` D 2 ` Dqvy Thus L D 3 ` D 2 ` D. The boundary conditions are 0 y 2 p1qvp1q y 1 p1qv 1 p1q ` y 1 p1qvp1q y 2 p1qr5vp1q 4v 1 p1qs 0 y 2 p0qvp0q y 1 p0qv 1 p0q ` yp0qv 2 p0q ` y 1 p0qvp0q yp0qv 1 p0q yp0qvp0q y 2 p0qvp0q ` y 1 p0qr7v 2 p0q 8v 1 p0q 6vp0qs The domain of the adjoint is then $ & vp0q 0 S 8v % 1 p0q 7v 2 p0q 0 5vp1q 4v 1 p1q 0 Neither operator is self adjoint since L L and S S. (c) We have the following operator and domain. α 1 yp0q ` α 2 y 1 p0q 0 L DpD ` q S β 1 yp1q ` β 2 y 1 p1q 0 It is straightforward to see that We then compute xqy, vy xy, qvy. xdpdy, vy ppxqry 1 vs 1 0 xpdy, Dvy ppxqry 1 vs 1 0 xdy, pdvy ppxqry 1 v yv 1 s 1 0 ` xy, DpDvy Summing yields L DpD ` q. For nonzero p, the boundary conditions are 0 y 1 p1qvp1q yp1qv 1 p1q y 1 p0qvp0q ` yp0qv 1 p0q y 1 p1qrvp1q ` β2 β 1 v 1 p1qs y 1 p0qrvp0q ` α2 α 1 v 1 p0qs The domain of the adjoint is then α 1 vp0q ` α 2 v S 1 p0q 0 β 1 vp1q ` β 2 v 1 p1q 0 When p, q are real and hence p p, q q, the formal operator is self adjoint. When additionally p 0, we have S S, and hence that L is self adjoint.

3 MATH 551 HOMEWORK II SOLUTIONS 3 2. Problem 2 (a) We have the following boundary value problem. u 2 pxq 9e 4x up0q 5 up1q 7 We have that u B satisfies u 2 B 0 and hence u B c 1 x ` c 2. Imposing boundary conditions yields the solution u B 12x 5. We have that u F satisfies u 2 F 9e4x with homogeneous boundary conditions. We find the eigenvalues and their corresponding eigenfunctions to be λ n pnπq 2 φ n pxq sinpnπxq, yielding the eigenfunction expansion 8ÿ x9e 4x, sinpnπxqy u F a n φ n a n λ n xsinpnπxq, sinpnπxqy 18rp 1qn e 4 1s nπp16 ` pnπq 2. n 1 Alternatively, we can solve directly to find u F 9 16 e4x ` b 1 x ` b 2. The boundary conditions then induce the system 9 16 ` b e4 ` b 1 ` b 2 0 This yields the following solution. u F 9 16 pe4x ` p1 e 4 qx 1q Summing gives us the solution to the boundary value problem u 9 16 e4x ` r12 ` 9 16 p1 e4 qsx (b) We have the following boundary value problem u 2 ` 8u 1 ` 12u 9 u 1 p0q ` 4up0q 5 u 1 pπq ` 4u 1 pπq 3 Letting wpxq e 4x upxq, we have a Sturm-Liouville problem for w: w 2 pxq 4wpxq e 4x pu 2 ` 8u 1 ` 12uq 9e 4x with the following boundary conditions. w 1 p0q u 1 p0q ` 4up0q 5 w 1 p1q e 4π ru 1 p1q ` 4up1qs 3e 4π The homogeneous equation has general solution w B c 1 e 2x ` c 2 e 2x. Applying the boundary conditions forces the solution w B pxq 2pe4π ` 1q 3e 6π 5 re2x ` e 4π e 2x s. We want w F satisfying w 2 F w F 9e 4x with homogeneous boundary conditions. We find the eigenvalues and their corresponding eigenfunctions to be λ n 4 ` n 2 n 0 φ n cospnxq, yielding an eigenfunction expansion 8ÿ 1 p 1q n e 4π w F a n φ n a n πpn 2 ` 16qpn ` 4q 2.

4 4 MATH 551 HOMEWORK II SOLUTIONS (a) By direct computation: 3. Problem 3 Lpe rx q pe rx q 2 ` 6pe rx q 1 ` 9e rx r 2 e rx ` 6re rx ` 9e rx pr ` 3q 2 e rx (b) Letting r 3, Lpe 3x q 0. Hence Ce 3x is a solution to Ly 0. (c) By the commuting of derivatives: (d) By direct computation: B r Lpzq B r pb 2 xz ` 6B x z ` 9zq pb 2 x ` 6B x ` 9qB r z LpB r zq LpB r pe rx qq B r Lpe rx q B r rpr ` 3q 2 e rx s pr ` 3qr2 ` xpr ` 3qse rx (e) Letting r 3 we see that Lpxe 3x q 0, giving us solutions y Cxe 3x. 4. Problem 4 (a) Let ϕ uv 3 u 1 v 2 ` u 2 v 1 u 3 v. Then ϕ 1 u 1 v 3 ` uv p4q u 2 v 2 u 1 v 3 ` u 3 v 1 ` u 2 v 2 u p4q v u 3 v 1 uv p4q vu p4q ulv vlu Therefore ulv vlu is an exact differential. (b) By part (a) and the FTC: ş 1 0 pulv vluqdx ş 1 0 ϕ1 dx ϕ 1 0 ruv 3 u 1 v 2 ` u 2 v 1 u 3 vs 1 0 (c) Since upbq 0 vpbq for b 0, 1, we are reduced to ϕ 1 0 ru 2 v 1 u 1 v 2 s 1 0. By other boundary conditions, ϕp1q 0 ϕp0q, and thus ş 1 pulv vluqdx 0. 0

5 MATH 551 HOMEWORK II SOLUTIONS 5 5. Problem 5 (b) Variation of parameters yields upxq ş 1 0 fpx 0qGpx, x 0 qdx 0 with x x ă x 0 Gpx, x 0 q x 0 x ą x 0 (c) We must ensure that Gpx, x 0 q satisfies G xx px, x 0 q δpx x 0 q Gp0, x 0 q 0 G x pl, x 0 q 0 Enforcing the boundary and jump conditions yields x x ă x 0 Gpx, x 0 q x 0 x ą x 0 (d) As usual upxq ş 1 0 fpx 0qGpx, x 0 qdx 0, except we now express Gpx, x 0 q as Gpx, x 0 q 2 8ÿ sinpnπx{lq sinpnπx 0 {Lq L pnπ{lq 2 n 1 6. Problem 6 (a) We have the following boundary value problem u 2 pxq fpxq up0q A u 1 plq B By 5(c), the homogenoeus BC solution is u F pxq ş L 0 fpx 0qGpx, x 0 qdx with x x ă x 0 Gpx, x 0 q x 0 x ą x 0 This yields the following conditions Gp0, x 0 q 0 G x p0, x 0 q 1 GpL, x 0 q x 0 G x pl, x 0 q 0 We find u B satisfying u u F ` u B in two ways. By Green s Formula: ş L 0 rupxqg xxpx, x 0 q u 2 pxqgpx, x 0 qsdx rug x px, x 0 q Gpx, x 0 qu 1 pxqs L 0 ş L 0 upxqδpx, x 0qdx şl 0 fpxqgpx, x 0qdx up0qg x p0, x 0 q GpL, x 0 qu 1 plq upxq u F pxq up0q ` xu 1 plq upxq u F pxq ` A ` BX Alternatively, u B solves u 2 B 0 with given boundary conditions, forcing u B pxq Ax ` B.

6 6 MATH 551 HOMEWORK II SOLUTIONS 7. Problem 7 (a) We have the boundary value problem u 2 ` u sin x up0q upπq 0. The general homogeneous solution is upxq c 1 sin x ` c 2 cos x. The boundary conditions force c 2 0, yielding φ h sin x. Then ş π 0 φ hpxqfpxqdx ş π 0 sin2 xdx ą 0. By the Fredholm alternative, the nonhomogeneous problem has no solutions. (c) We have the boundary value problem u 2 u sin x up0q upπq 0. The general homogeneous solution is upxq c 1 e x ` c 2 e x. The boundary conditions force c 1 c 2 0, yielding φ h 0. By the Fredholm alternative, there exists a unique nonhomogeneous solution.

17.2 Nonhomogeneous Linear Equations. 27 September 2007

17.2 Nonhomogeneous Linear Equations 27 September 2007 Nonhomogeneous Linear Equations The differential equation to be studied is of the form ay (x) + by (x) + cy(x) = G(x) (1) where a 0, b, c are given