Presentations

Pacing Tracker

  • The quizzes have included questions for 22 objectives. How many have you passed? What are you plans to master those that you haven't mastered yet?
  • We've finished units 1 through 4. Have you started your self-directed learning project for each unit?
  • The 6th project can be over any topic from the entire semester. Feel free to get started on this one as soon as you have an idea.
  • Remember you can submit only one SDL project per week. Plan ahead and don't let yourself get behind.

Brain Gains

  • Set up an integral in polar coordinates that would give the mass of laminar region in the plane that lies inside the circle $x^2+y^2=9$ and has density given by $\delta (x,y) = y^2$.

Solution (Part of problem 18)

  • A solid lies in the first octant and is bounded by the coordinate planes ($x = 0$, $y = 0$, $z = 0$), the plane $y + z = 2$, and the surface $x = 4 − y^2$. Sketch the solid and then set up an iterated integral that would give its volume using the order of integration $dxdzdy$.

Solution (Part of problem 19)

  • A triangular wedge lies in the first octant and is bounded by the planes $\ds\frac{y}{7}+\frac{z}{5}=1$ and $x=12$. The density $\delta$ of the wedge is constant. The mass of this wedge is given by the integral $\ds\int_{0}^{12}\int_{0}^{7}\int_{0}^{5(1-y/7)}\delta dzdydx$. Set up an integral formula to compute $\bar y$, and then sketch the region.

Solution (Part of problem 20)

  • A wire that lies along the curve $C$ with parametrization $\vec r(t) = (5 \cos t, 5 \sin t)$ for $0 \leq t \leq π$. Set up an integral formula to compute the $y$-coordinate of the centroid of the wire. (Recall that $ds = \left|\frac{d\vec r}{dt}\right|dt$.)

Solution (Part of problem 21)

  • Set up an iterated triple integral using Cartesian coordinates that gives the volume inside a sphere of radius $a$ whose equation is $x^2+y^2+z^2=a^2$.

Solution (Part of problem 22)

Recall: Given two vectors $\vec u = (u_1,u_2,u_3)$ and $\vec v = (v_1,v_2,v_3)$, the cross product of the two vectors
  1. is orthogonal to both $\vec u$ and $\vec v$,
  2. has a magnitude $|\vec u\times\vec v|$ equal to the area of the parallelogram formed by $\vec u$ and $\vec v$, and
  3. can be computed by the formula $$\vec u\times\vec v=(u_2v_3-u_3v_2,u_3v_1-u_1v_3,u_1v_2-u_2v_1).$$

Let $P=(3,0,0)$, $Q=(0,2,0)$, and $R=(0,0,1)$.

  • Find a vector orthogonal to both $\vec {PQ}=\left<-3,2,0\right>$ and $\vec {PR}=\left<-3,0,1\right>$.

Solution

$$\left|\begin{array}{ccc}\hat{i}&\hat{j}&\hat{k}\\ -3 & 2& 0 \\ -3& 0 & 1\end{array} \right|=\left<2,3, 6\right>.$$

  • Find the area of the triangle $\Delta PQR$.

Solution

We need half the area of the parallelogram formed from the vector above. We compute $$|\left<2,3, 6\right>| = \sqrt{4+9+36} = 7,$$ which means the area is 7/2.

  • Suppose that $S=(x,y,z)$ is a point in the plane that passes through $P$, $Q$, and $R$, and note that $\vec {PS} = \left<x-3,y-0,z-0\right>.$ First compute $(\vec {PQ}\times \vec {PR})\cdot \vec {PS}$. Then explain why this dot product equals zero.

Solution

We have $$(\vec {PQ}\times \vec {PR})\cdot \vec {PS}=\left<2,3, 6\right>\cdot \left<x-3,y-0,z-0\right> = 2(x-3)+3(y-0)+6(z-0).$$ The dot product equals zero because $(\vec {PQ}\times \vec {PR})$ is orthogonal to any vector in the plane formed by $\vec {PQ}$ and $\vec {PR}$. This means an equation of the plane through $P$, $Q$, and $R$ is $$2(x-3)+3(y-0)+6(z-0)=0.$$

  • Convert the integral $\int_0^{6\sqrt{2}/2} \int_{y}^{\sqrt{36-y^2}} x \, dx \, dy$ into polar coordinates.

Solution

A solution is $\int_{0}^{\pi/4} \int_0^{6} (r\cos\theta) \, r \, dr\,d\theta$.

  • Draw the region in the first octant (all variables positive) that is bounded by the plane $\frac{x}{2}+\frac{y}{3}+\frac{z}{5}=1$. Then set up an integral to compute the volume of this region.

Solution

The region is a triangular pyramid. The plane passes through $(2,0,0)$, $(0,3,0)$, and $(0,0,5)$, so it is the region in space underneath this triangle. One integral (of 6 possible) that gives the volume is $$\int_{0}^{2}\int_{0}^{3(1-\frac{x}{2})}\int_{0}^{5(1-\frac{x}{2}-\frac{y}{3})}dzdydx.$$

Group problems

  1. Set up an integral formula to compute each of the following: (Use the Mathematica notebook Integration.nb to check your bounds.)
    • The mass of a disc that lies inside the circle $x^2+y^2=9$ and has density function given by $\delta = x+10$
    • The $x$-coordinate of the center of mass (so $\bar x$) of the disc above.
    • The volume of the solid object in the first octant (all variables positive) that lies under the plane $2x+3y+6z=6$ (so $\frac{x}{3}+\frac{y}{2}+\frac{z}{1}=1$).
    • The $y$-coordinate of the center-of-mass (so $\bar y$) of previous object.
  2. A wire lies along the curve $C$ parametrized by $\vec r(t) = (t^2+1, 3t, t^3)$ for $-1\leq t\leq 2$.
    • Compute $ds$. (Remember - a little distance equals the product of the speed and a little time.)
    • Set up integral formulas to find $\bar x$, then $\bar y$, then $\bar z$, for the centroid of $C$.
  3. Consider $\int_{0}^{4}\int_{x}^{4}\cos(y^2)dydx$.
    • Draw the region described by the bounds.
    • Swap the order of the bounds on the integral (use $dxdy$ instead of $dydx$).
    • Actually compute the integral.

Problem Set
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