Math 234 Worksheet 4: Line integrals II 1. Do Problem 2 (iii) of
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Math 234 Worksheet 4: Line integrals II 1. Do Problem 2 (iii) of
Math 234 Worksheet 4: Line integrals II 1. Do Problem 2 (iii) of Worksheet 3 using Green’s theorem. 2. Let F~ = (−y, x). Let C be the curve x2 + y 2 = 1 oriented counter clockwise. (i) Sketch the vector field along the curve C. I ~ ds where N ~ is the outward unit (ii) Guess what would be the flux F~ · N C normal vector for the curve C. (iii) Compute the integral with and without Green’s theorem. ~ is the outward unit normal vector for (iv) Now suppose that F~ = (x, y) and N H ~ ds ( = , > , < ) 0. the curve C. Circle one of the followings: F~ · N C 3. (i) Let R be a simply-connected region in the plane and C be the boundary curve oriented counter clockwise. Show that, by using Green’s theorem, I 1 −ydx + xdy. Area of R = 2 C x 2 y 2 + = 1 (a, b > 0). (ii) Compute the area of an ellipse a b Hint: Use the parametrization x = a cos t, y = b sin t. 4. Let R be the region in the first quadrant bounded by x, y axis and the circle x2 + y 2 = 1 and C be I the boundary curve of R with the counter clockwise orientation. Compute y 3 dx − x3 dy. C Review 1 (Flux integral) The flux of a vector field F~ (x, y) = (P (x, y), Q(x, y)) Z ~ ds. In particular, if C is ~ is defined by F~ · N across the curve C in the direction N C ~ is the outward unit normal vector to the curve C, oriented counter clockwise and N ~ then N ds = (dy, −dx) and Z Z ~ ~ F · N ds = P (x, y)dy − Q(x, y)dx. C C Review 2 (Green’s Theorem) Let R be a simply connected region in the plan, C ~ be the outward be the boundary curve of R with the counter clockwise orientation, N ~ unit normal vector to the curve C, and F (x, y) = (P (x, y), Q(x, y)). Then I Z ZZ ~ F · d~x = P (x, y)dx + Q(x, y)dy = (Qx − Py )dA. C C R We also have the following equivalent statement for the flux integral I ZZ ~ ~ F · N ds = (Px + Qy )dA. C R ~ = ( ∂ , ∂ ) and F~ . It is called Here, note that Px + Qy is fomally the dot product of ∇ ∂x ∂y ~ ~ ~ ~ the divergence of F and denoted by ∇ · F or div F . Answers 1. By Green’s theorem, the line integral is equal to Z 1Z x 1 ydydx = . 15 0 x2 2. (i) The vectors should be tangential to the curve C of the same length. ~ are perpendicular at each point on the curve. (ii) 0, since F~ and N (iii) Without Green’s theorem: use the parametrization x(t) = cos t, y(t) = sin t with dx = − sin tdt, dy = cos tdt. Z Z Z 2π P dy − Qdx = −ydy − xdx = − sin t cos tdt − cos t(− sin tdt) = 0. C C 0 Let R be the region x2 + y 2 ≤ 1 enclosed by C. Then by Green’s theorem, Z ZZ ~ ~ ~ · F~ dA = 0, F · N ds = ∇ C R ~ · F~ = Px + Qy = 0. since ∇ H ~ ds > 0, since F~ is parallel to N ~. (iv) C F~ · N RR 3. (i) Hint: R 1dA = Area of R. (ii) Ans: πab. 4. Note that R = {(r, θ) : 0 ≤ r ≤ 1, 0 ≤ θ ≤ π/2} in polar coordinates. With P = y 3 and Q = −x3 , Green’s theorem says that the line integral is equal to ZZ ZZ Z π/2 Z 1 3π 2 2 x + y dA = −3 r2 rdrdθ = − . (Qx − Py )dA = −3 8 R 0 0 R 2