Chapter 10.4, Problem 50E

(a)

To determine

To find: The angle between the two planes $x-3y+2z=0$ and $3x+2y-5z=0$ .

Answer to Problem 50E

The angle between the two planes $x-3y+2z=0$ and $3x+2y-5z=0$ is $124.30°$ .

Explanation of Solution

Given information:

The equation of two planes $x-3y+2z=0$ and $3x+2y-5z=0$ .

Calculation:

Compare the equation of the plane with $ax+by+cz=d$ .

So, the normal vector for plane $x-3y+2z=0$ is $\langle 1,-3,2\rangle$ and normal vector for plane $3x+2y-5z=0$ is $\langle 3,2,-5\rangle$ .

The angle between the two planes is equal to the angles between their normal vectors.

Use the formula for angle between two vectors $u$ and $v$ .

  $\cos \theta =\frac{u\cdot v}{\Vert u\Vert \Vert v\Vert }$

The dot product of both the vectors $\langle 1,-3,2\rangle$ and $\langle 3,2,-5\rangle$ .

  $\begin{array}{c}\langle 1,-3,2\rangle \cdot \langle 3,2,-5\rangle =1\times 3+\left(-3\right)\times 2+2\times -5\\ =3-6-10\\ =-13\end{array}$

Use the formula for magnitude of vector $\langle 1,-3,2\rangle$ .

  $\begin{array}{c}\Vert \langle 1,-3,2\rangle \Vert =\sqrt{{\left(1\right)}^2+{\left(-3\right)}^2+{\left(2\right)}^2}\\ =\sqrt{1+9+4}\\ =\sqrt{14}\end{array}$

Use the formula for magnitude of vector $\langle 3,2,-5\rangle$ .

  $\begin{array}{c}\Vert \langle 3,2,-5\rangle \Vert =\sqrt{{\left(3\right)}^2+{\left(2\right)}^2+{\left(-5\right)}^2}\\ =\sqrt{9+4+25}\\ =\sqrt{38}\end{array}$

Substitute all the values in the formula for angle.

  $\begin{array}{c}\cos \theta =\frac{\langle 1,-3,2\rangle \cdot \langle 3,2,-5\rangle }{\Vert \langle 1,-3,2\rangle \Vert \Vert \langle 3,2,-5\rangle \Vert }\\ =\frac{-13}{\sqrt{14}\times \sqrt{38}}\\ =\frac{-13\sqrt{133}}{266}\end{array}$

The solution for the trigonometric equation $\cos \theta =\frac{-13\sqrt{133}}{266}$ is $\theta =124.30°$ .

Therefore, the angle between the two planes $x-3y+2z=0$ and $3x+2y-5z=0$ is $124.30°$ .

(b)

To determine

To find: The parametric equations of the line of intersection for the planes $x-3y+2z=0$ and $3x+2y-5z=0$ .

Answer to Problem 50E

The parametric equations of the line of intersection of the planes $x-3y+2z=0$ and $3x+2y-5z=0$ is $x=t$ , $y=t$ and $z=t$ .

Explanation of Solution

Given information:

The equation of two planes $x-3y+2z=0$ and $3x+2y-5z=0$ .

Calculation:

Multiply the first equation of plane by $3$ and subtract from the second plane.

  $\begin{array}{c}3x+2y-5z-3\left(x-3y+2z\right)=0\\ 3x+2y-5z-3x+9y-6z=0\\ 11y-11z=0\\ y=z\end{array}$

Substitute $y=z$ in the equation of plane $x-3y+2z=0$ .

  $\begin{array}{c}x-3y+2z=0\\ x-3z+2z=0\\ x-z=0\\ x=z\end{array}$

Finally assume that $t=z$ .

Therefore, the parametric equations of the line of intersection of the planes $x-3y+2z=0$ and $3x+2y-5z=0$ is $x=t$ , $y=t$ and $z=t$ .