Let I=∫∫∫4zdV over the region D
where D is the parallelepiped
{(x,y,z):3≤y+z≤8,−2≤z−y≤5,1≤x−y≤3.}
Find an appropriate transformation that maps D to a rectangular box in uvw space.
Then use the Jacobian to simplify and evaluate I.
I=
Let I=∫∫∫4zdV over the region D where D is the parallelepiped {(x,y,z):3≤y+z≤8,−2≤z−y≤5,1≤x−y≤3.}...
(3) Let D be the region in the first quadrant between the circles 12 + y y1 and 2. Sketch the region D and find a C transformation T that maps a rectangular region D (where the sides of D are parallel to the coordinate axes) onto D
Evaluate the integral: (x) dzdrdy, where B is the cylinder over the rectangular region R-(z, y) є R2 :-1 z 1,-2 y of the zy-plane, bounded below by the surface ะ1-sin|cos y and above by the sur- 2) face of elliptical paraboloid 22-2-4-9 Evaluate the integral: (x) dzdrdy, where B is the cylinder over the rectangular region R-(z, y) є R2 :-1 z 1,-2 y of the zy-plane, bounded below by the surface ะ1-sin|cos y and above by the sur-...
14) Consider the parallelepiped D determined by the vectors (2,-1,2), (1,3, 1), and (2,-1,1). Let T(z, y, 2)a-ytz. Consider the integral I - JSsD TdV. Using the Change of Variables Theorem, write I as an integral of the form T(r(r, s,t), v(r, s, t), z(r, s,t))lJ(r,s, t) dr ds dt for a suitable linear change of variables (r, s, t) (, y,z). The Jacobian J(r,s,t) you get here should be a constant function. 14) Consider the parallelepiped D determined by...
2. Use the transformation X= 2ut 3v and y=3u-Zv to evaluate (xrydd where D is the rectangular region with vertices (0,0),(2,3),65,1),(5,2).
a. Find the Jacobian of the transformation x= 34, y = uv and sketch the region G: 3531 56, 15 uv s 2, in the uv-plane. 6 2 b. Then use -- S S «y dx dy=[[«guw, rus),Mw.v) du dv to transform the integrat $ žay dx into an integral over 6, and evaluate both integrals. R G a. The Jacobian is Choose the correct sketch of the region G below. OC. D. OA. AV 6- 12 b. Write the...
Consider the vector field F(x, y, z) = 8x^2 + 3y, −5x^2y − 4y^2, 6x^2 + 7y − 8 which is defined on all of double-struck R3, and let F be the rectangular solid region F = {(x, y, z) | 0 ≤ x ≤ a, 0 ≤ y ≤ b, −1 ≤ z ≤ 1} where a > 0 and b > 0 are constants. Determine the values of a and b that will make the flux of F...
2. You are given the following multivariate PDF 3 (x, y, z) else s fxx.2(z, y, z)- I, 0 where S-((z, y,2)lr'ザ+8-1) (a) (5 points) Let T be the set of all points that lie inside the largest cylinder by volume that can be inscribed in the region of S. Similarly let U be the set of all points that lie inside the largest cube that can be inscribed in the region of S. What would the probabilities P(X,Y, Z)...
(7 pts.) Let f(x, y, z) = "y and let R be the region {(x, y, z) |2 < x < 4,0 Sy < 3,15 zse}. 2 Evaluate | $180,0,.2) av. R
Question 6 (3 points) a -- 2 points) Find the Jacobian of the transformation the shear transformation: x = au + bv + cw, y=dy + ew, and z fw, where a, b, c, d, e, and f are positive real numbers, and describe the how the volume of the unit cube in uvw coordinates compares to the volume of its transformation in Cartesian coordinates. = b -- 1 point) State one example of a practical application shown in lecture...
1/3 x + y 7. Consider dA where R is the region bounded by the triangle with vertices (0,0), (2,0), V= x+y X-y and (0,-2). The change of variables u=- defines a transformation T(x,y)=(u,v) from the xy-plane 2 to the uv-plane. (a) (10 pts) Write S (in terms of u and v) using set- builder notation, where T:R→S. Use T to help you sketch S in the uv-plane by evaluating T at the vertices. - 1 a(u,v) (b) (4 pts)...