week 6 group project
1. use the chain rule to find the derivative of each function.
a. $y=(x^{3}+1)^{5}$
b. $y = sqrt{3x^{3}-4}$
c. $y=sin x^{4}$
d. $y=(x^{2}+3)(2x^{5}+9)^{4}$
e. $y=sqrt3{-x^{2}+2}$
f. $y=sec^{2}5x$
2. find equations of all lines tangent to $x + y^{3}-y = 1$ at $x = 1$.
3. an observer is 20 m above the ground floor of a large hotel atrium looking at a glass enclosed elevator shaft that is 20 m horizontally from the observer. the angle of elevation of the elevator is the angle that the observers line of sight makes with the horizontal (it may be positive or negative). assuming that the elevator rises at a rate of 5 m/s, what is the rate of change of the angle of elevation when the elevator is 10 m above the ground? when the elevator is 40 m above the ground?

Question

week 6 group project
1. use the chain rule to find the derivative of each function.
 a. $y=(x^{3}+1)^{5}$
 b. $y = sqrt{3x^{3}-4}$
 c. $y=sin x^{4}$
 d. $y=(x^{2}+3)(2x^{5}+9)^{4}$
 e. $y=sqrt3{-x^{2}+2}$
 f. $y=sec^{2}5x$
2. find equations of all lines tangent to $x + y^{3}-y = 1$ at $x = 1$.
3. an observer is 20 m above the ground floor of a large hotel atrium looking at a glass enclosed elevator shaft that is 20 m horizontally from the observer. the angle of elevation of the elevator is the angle that the observers line of sight makes with the horizontal (it may be positive or negative). assuming that the elevator rises at a rate of 5 m/s, what is the rate of change of the angle of elevation when the elevator is 10 m above the ground? when the elevator is 40 m above the ground?

Accepted Answer

### 1a.
# Explanation:
## Step1: Let $u = x^{3}+1$
$y = u^{5}$
## Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$
$\frac{du}{dx}=3x^{2}$, $\frac{dy}{du} = 5u^{4}$
## Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$
Substitute $u = x^{3}+1$ into $\frac{dy}{du}$: $\frac{dy}{dx}=5(x^{3}+1)^{4}\cdot3x^{2}=15x^{2}(x^{3}+1)^{4}$
# Answer:
$15x^{2}(x^{3}+1)^{4}$

### 1b.
# Explanation:
## Step1: Let $u = 3x^{3}-4$
$y=\sqrt{u}=u^{\frac{1}{2}}$
## Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$
$\frac{du}{dx}=9x^{2}$, $\frac{dy}{du}=\frac{1}{2}u^{-\frac{1}{2}}$
## Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$
Substitute $u = 3x^{3}-4$ into $\frac{dy}{du}$: $\frac{dy}{dx}=\frac{1}{2}(3x^{3}-4)^{-\frac{1}{2}}\cdot9x^{2}=\frac{9x^{2}}{2\sqrt{3x^{3}-4}}$
# Answer:
$\frac{9x^{2}}{2\sqrt{3x^{3}-4}}$

### 1c.
# Explanation:
## Step1: Let $u = x^{4}$
$y=\sin u$
## Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$
$\frac{du}{dx}=4x^{3}$, $\frac{dy}{du}=\cos u$
## Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$
Substitute $u = x^{4}$ into $\frac{dy}{du}$: $\frac{dy}{dx}=\cos(x^{4})\cdot4x^{3}=4x^{3}\cos(x^{4})$
# Answer:
$4x^{3}\cos(x^{4})$

### 1d.
# Explanation:
## Step1: Use the product rule $(uv)^\prime = u^\prime v+uv^\prime$ where $u=x^{2}+3$, $v=(2x^{5}+9)^{4}$
Find $u^\prime$ and $v^\prime$. $u^\prime = 2x$
For $v=(2x^{5}+9)^{4}$, let $t = 2x^{5}+9$, then $v = t^{4}$. $\frac{dt}{dx}=10x^{4}$, $\frac{dv}{dt}=4t^{3}$, so $v^\prime=\frac{dv}{dt}\cdot\frac{dt}{dx}=4(2x^{5}+9)^{3}\cdot10x^{4}=40x^{4}(2x^{5}+9)^{3}$
## Step2: Apply the product rule
$(uv)^\prime=2x(2x^{5}+9)^{4}+(x^{2}+3)\cdot40x^{4}(2x^{5}+9)^{3}=2x(2x^{5}+9)^{3}(2x^{5}+9 + 20x^{4}(x^{2}+3))=2x(2x^{5}+9)^{3}(2x^{5}+9+20x^{6}+60x^{4})$
# Answer:
$2x(2x^{5}+9)^{3}(2x^{5}+9 + 20x^{6}+60x^{4})$

### 1e.
# Explanation:
## Step1: Let $u=-x^{2}+2$
$y = u^{\frac{1}{3}}$
## Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$
$\frac{du}{dx}=-2x$, $\frac{dy}{du}=\frac{1}{3}u^{-\frac{2}{3}}$
## Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$
Substitute $u=-x^{2}+2$ into $\frac{dy}{du}$: $\frac{dy}{dx}=\frac{1}{3}(-x^{2}+2)^{-\frac{2}{3}}\cdot(-2x)=-\frac{2x}{3\sqrt[3]{(-x^{2}+2)^{2}}}$
# Answer:
$-\frac{2x}{3\sqrt[3]{(-x^{2}+2)^{2}}}$

### 1f.
# Explanation:
## Step1: Let $u=\sec(5x)$
$y = u^{2}$
## Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$
For $u=\sec(5x)$, let $t = 5x$, then $u=\sec t$. $\frac{dt}{dx}=5$, $\frac{du}{dt}=\sec t	an t$, so $\frac{du}{dx}=5\sec(5x)	an(5x)$; $\frac{dy}{du}=2u$
## Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$
Substitute $u=\sec(5x)$ into $\frac{dy}{du}$: $\frac{dy}{dx}=2\sec(5x)\cdot5\sec(5x)	an(5x)=10\sec^{2}(5x)	an(5x)$
# Answer:
$10\sec^{2}(5x)	an(5x)$

### 2.
# Explanation:
## Step1: Differentiate $x + y^{3}-y = 1$ implicitly with respect to $x$
$1 + 3y^{2}y^\prime-y^\prime=0$
## Step2: Solve for $y^\prime$
$y^\prime(3y^{2}-1)=-1$, so $y^\prime=\frac{-1}{3y^{2}-1}$
## Step3: When $x = 1$, substitute into the original equation $1 + y^{3}-y = 1$, which gives $y^{3}-y=0$, $y(y - 1)(y + 1)=0$, so $y=0,1,-1$
## Step4: Find the slopes at these $y$ - values
When $y = 0$, $y^\prime=-1$; when $y = 1$, $y^\prime=-\frac{1}{2}$; when $y=-1$, $y^\prime=-\frac{1}{2}$
## Step5: Use the point - slope form $y - y_{0}=m(x - x_{0})$
For $(x_{0}=1,y_{0}=0)$ and $m=-1$, the equation is $y-0=-1(x - 1)$, i.e., $y=-x + 1$
For $(x_{0}=1,y_{0}=1)$ and $m=-\frac{1}{2}$, the equation is $y - 1=-\frac{1}{2}(x - 1)$, i.e., $y=-\frac{1}{2}x+\frac{3}{2}$
For $(x_{0}=1,y_{0}=-1)$ and $m=-\frac{1}{2}$, the equation is $y + 1=-\frac{1}{2}(x - 1)$, i.e., $y=-\frac{1}{2}x-\frac{1}{2}$
# Answer:
$y=-x + 1$, $y=-\frac{1}{2}x+\frac{3}{2}$, $y=-\frac{1}{2}x-\frac{1}{2}$

### 3.
# Explanation:
## Step1: Let $y$ be the height of the elevator above the observer's horizontal line of sight, so $y$ is the vertical distance from the observer's horizontal line to the elevator. The horizontal distance $x = 20$ m. Let $	heta$ be the angle of elevation. Then $	an	heta=\frac{y}{20}$
Differentiate both sides with respect to time $t$: $\sec^{2}	heta\frac{d	heta}{dt}=\frac{1}{20}\frac{dy}{dt}$
## Step2: When the elevator is 10 m above the ground, $y=10 - 20=-10$ m
$	an	heta=\frac{-10}{20}=-\frac{1}{2}$, $\sec^{2}	heta=1+	an^{2}	heta=1+\frac{1}{4}=\frac{5}{4}$, $\frac{dy}{dt}=5$ m/s
Substitute into $\sec^{2}	heta\frac{d	heta}{dt}=\frac{1}{20}\frac{dy}{dt}$: $\frac{5}{4}\frac{d	heta}{dt}=\frac{1}{20}	imes5$, $\frac{d	heta}{dt}=\frac{1}{5}$ rad/s
## Step3: When the elevator is 40 m above the ground, $y=40 - 20 = 20$ m
$	an	heta=\frac{20}{20}=1$, $\sec^{2}	heta=1 + 1=2$, $\frac{dy}{dt}=5$ m/s
Substitute into $\sec^{2}	heta\frac{d	heta}{dt}=\frac{1}{20}\frac{dy}{dt}$: $2\frac{d	heta}{dt}=\frac{1}{20}	imes5$, $\frac{d	heta}{dt}=\frac{1}{8}$ rad/s
# Answer:
When the elevator is 10 m above the ground, $\frac{d	heta}{dt}=\frac{1}{5}$ rad/s; when the elevator is 40 m above the ground, $\frac{d	heta}{dt}=\frac{1}{8}$ rad/s

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QUESTION IMAGE

Question

Explanation:

1a.

Step1: Let $u = x^{3}+1$

Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$

Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$

Step1: Let $u = 3x^{3}-4$

Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$

Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$

Step1: Let $u = x^{4}$

Step2: Find $\frac{du}{dx}$ and $\frac{dy}{du}$

Step3: Apply chain - rule $\frac{dy}{dx}=\frac{dy}{du}\cdot\frac{du}{dx}$

Answer:

1b.