5. find the volume of the parallelepiped with edges $\vec{u}$, $\vec{v}$, and $\vec{w}$:

(a) $\vec{u} = \langle 0, 1, -2 \
angle$, $\vec{v} = \langle -3, -4, 5 \
angle$, $\vec{w} = \langle -6, 7, 8 \
angle$.

(b) $\vec{u} = \langle 0, -3, -6 \
angle$, $\vec{v} = \langle 1, -4, 7 \
angle$, $\vec{w} = \langle -2, 5, 8 \
angle$.

(c) $\vec{u} = \langle 2, -1, -3 \
angle$, $\vec{v} = \langle 4, -2, 1 \
angle$, $\vec{w} = \langle 3, -4, 5 \
angle$.

(d) $\vec{u} = \langle 3, 0, 0 \
angle$, $\vec{v} = \langle 0, 4, 0 \
angle$, $\vec{w} = \langle 0, 0, 5 \
angle$.

(e) $\vec{u} = \langle 3, 135, 246 \
angle$, $\vec{v} = \langle 0, 4, 159 \
angle$, $\vec{w} = \langle 0, 0, 5 \
angle$.

Question

5. find the volume of the parallelepiped with edges $\vec{u}$, $\vec{v}$, and $\vec{w}$:

(a) $\vec{u} = \langle 0, 1, -2 \
angle$, $\vec{v} = \langle -3, -4, 5 \
angle$, $\vec{w} = \langle -6, 7, 8 \
angle$.

(b) $\vec{u} = \langle 0, -3, -6 \
angle$, $\vec{v} = \langle 1, -4, 7 \
angle$, $\vec{w} = \langle -2, 5, 8 \
angle$.

(c) $\vec{u} = \langle 2, -1, -3 \
angle$, $\vec{v} = \langle 4, -2, 1 \
angle$, $\vec{w} = \langle 3, -4, 5 \
angle$.

(d) $\vec{u} = \langle 3, 0, 0 \
angle$, $\vec{v} = \langle 0, 4, 0 \
angle$, $\vec{w} = \langle 0, 0, 5 \
angle$.

(e) $\vec{u} = \langle 3, 135, 246 \
angle$, $\vec{v} = \langle 0, 4, 159 \
angle$, $\vec{w} = \langle 0, 0, 5 \
angle$.

Accepted Answer

### Part (a)
# Explanation:
## Step1: Recall the formula for the volume of a parallelepiped formed by vectors $\vec{u}$, $\vec{v}$, $\vec{w}$ is the absolute value of the scalar triple product $|\vec{u} \cdot (\vec{v} \times \vec{w})|$. First, find $\vec{v} \times \vec{w}$.
Given $\vec{v}=\langle - 3,-4,5
angle$ and $\vec{w}=\langle - 6,7,8
angle$, the cross product $\vec{v}\times\vec{w}=\begin{vmatrix}\vec{i}&\vec{j}&\vec{k}\-3&-4&5\-6&7&8\end{vmatrix}$
$$
\begin{align*}
\vec{v}\times\vec{w}&=\vec{i}((-4)\times8 - 5\times7)-\vec{j}((-3)\times8-5\times(-6))+\vec{k}((-3)\times7-(-4)\times(-6))\
&=\vec{i}(-32 - 35)-\vec{j}(-24 + 30)+\vec{k}(-21-24)\
&=\langle - 67,-6,-45
angle
\end{align*}
$$
## Step2: Now find the dot product of $\vec{u}=\langle0,1, - 2
angle$ and $\vec{v}\times\vec{w}=\langle - 67,-6,-45
angle$
$\vec{u}\cdot(\vec{v}\times\vec{w})=0\times(-67)+1\times(-6)+(-2)\times(-45)=- 6 + 90 = 84$
## Step3: Take the absolute value to get the volume.
$|\vec{u}\cdot(\vec{v}\times\vec{w})| = |84|=84$
# Answer: 84

### Part (b)
# Explanation:
## Step1: Find $\vec{v}\times\vec{w}$ where $\vec{v}=\langle1,-4,7
angle$ and $\vec{w}=\langle - 2,5,8
angle$
$\vec{v}\times\vec{w}=\begin{vmatrix}\vec{i}&\vec{j}&\vec{k}\1&-4&7\-2&5&8\end{vmatrix}$
$$
\begin{align*}
\vec{v}\times\vec{w}&=\vec{i}((-4)\times8-7\times5)-\vec{j}(1\times8 - 7\times(-2))+\vec{k}(1\times5-(-4)\times(-2))\
&=\vec{i}(-32-35)-\vec{j}(8 + 14)+\vec{k}(5 - 8)\
&=\langle - 67,-22,-3
angle
\end{align*}
$$
## Step2: Find the dot product of $\vec{u}=\langle0,-3,-6
angle$ and $\vec{v}\times\vec{w}=\langle - 67,-22,-3
angle$
$\vec{u}\cdot(\vec{v}\times\vec{w})=0\times(-67)+(-3)\times(-22)+(-6)\times(-3)=66 + 18=84$
## Step3: Take the absolute value.
$|\vec{u}\cdot(\vec{v}\times\vec{w})|=|84| = 84$
# Answer: 84

### Part (c)
# Explanation:
## Step1: Find $\vec{v}\times\vec{w}$ where $\vec{v}=\langle4,-2,1
angle$ and $\vec{w}=\langle3,-4,5
angle$
$\vec{v}\times\vec{w}=\begin{vmatrix}\vec{i}&\vec{j}&\vec{k}\4&-2&1\3&-4&5\end{vmatrix}$
$$
\begin{align*}
\vec{v}\times\vec{w}&=\vec{i}((-2)\times5-1\times(-4))-\vec{j}(4\times5 - 1\times3)+\vec{k}(4\times(-4)-(-2)\times3)\
&=\vec{i}(-10 + 4)-\vec{j}(20 - 3)+\vec{k}(-16 + 6)\
&=\langle - 6,-17,-10
angle
\end{align*}
$$
## Step2: Find the dot product of $\vec{u}=\langle2,-1,-3
angle$ and $\vec{v}\times\vec{w}=\langle - 6,-17,-10
angle$
$\vec{u}\cdot(\vec{v}\times\vec{w})=2\times(-6)+(-1)\times(-17)+(-3)\times(-10)=-12 + 17+30 = 35$
## Step3: Take the absolute value.
$|\vec{u}\cdot(\vec{v}\times\vec{w})|=|35| = 35$
# Answer: 35

### Part (d)
# Explanation:
## Step1: Find $\vec{v}\times\vec{w}$ where $\vec{v}=\langle0,4,0
angle$ and $\vec{w}=\langle0,0,5
angle$
$\vec{v}\times\vec{w}=\begin{vmatrix}\vec{i}&\vec{j}&\vec{k}\0&4&0\0&0&5\end{vmatrix}$
$$
\begin{align*}
\vec{v}\times\vec{w}&=\vec{i}(4\times5-0\times0)-\vec{j}(0\times5 - 0\times0)+\vec{k}(0\times0-4\times0)\
&=\langle20,0,0
angle
\end{align*}
$$
## Step2: Find the dot product of $\vec{u}=\langle3,0,0
angle$ and $\vec{v}\times\vec{w}=\langle20,0,0
angle$
$\vec{u}\cdot(\vec{v}\times\vec{w})=3\times20+0\times0 + 0\times0=60$
## Step3: Take the absolute value.
$|\vec{u}\cdot(\vec{v}\times\vec{w})|=|60| = 60$
# Answer: 60

### Part (e)
# Explanation:
## Step1: Find $\vec{v}\times\vec{w}$ where $\vec{v}=\langle0,4,159
angle$ and $\vec{w}=\langle0,0,5
angle$
$\vec{v}\times\vec{w}=\begin{vmatrix}\vec{i}&\vec{j}&\vec{k}\0&4&159\0&0&5\end{vmatrix}$
$$
\begin{align*}
\vec{v}\times\vec{w}&=\vec{i}(4\times5-159\times0)-\vec{j}(0\times5 - 159\times0)+\vec{k}(0\times0-4\times0)\
&=\langle20,0,0
angle
\end{align*}
$$
## Step2: Find the dot product of $\vec{u}=\langle3,135,246
angle$ and $\vec{v}\times\vec{w}=\langle20,0,0
angle$
$\vec{u}\cdot(\vec{v}\times\vec{w})=3\times20+135\times0+246\times0 = 60$
## Step3: Take the absolute value.
$|\vec{u}\cdot(\vec{v}\times\vec{w})|=|60| = 60$
# Answer: 60

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QUESTION IMAGE

Question

Explanation:

Part (a)

Step1: Recall the formula for the volume of a parallelepiped formed by vectors \(\vec{u}\), \(\vec{v}\), \(\vec{w}\) is the absolute value of the scalar triple product \(|\vec{u} \cdot (\vec{v} \times \vec{w})|\). First, find \(\vec{v} \times \vec{w}\).

Step2: Now find the dot product of \(\vec{u}=\langle0,1, - 2

Step3: Take the absolute value to get the volume.

Step1: Find \(\vec{v}\times\vec{w}\) where \(\vec{v}=\langle1,-4,7

Step2: Find the dot product of \(\vec{u}=\langle0,-3,-6

Step3: Take the absolute value.

Step1: Find \(\vec{v}\times\vec{w}\) where \(\vec{v}=\langle4,-2,1

Step2: Find the dot product of \(\vec{u}=\langle2,-1,-3

Step3: Take the absolute value.

Answer:

Part (b)