Calculus for Team-Based Inquiry Learning: 2022 Edition

(a)

Draw a diagram illustrating how the box is created.

(b)

Explain why the volume of the box is a function of the side length \(x\) of the cutout squares.

(c)

Express the volume of the box \(V\) as a function of the length of the cuts \(x\text{.}\)

(d)

What is a realistic domain of the function \(V(x)\text{?}\)

(e)

What cut length \(x\) maximizes the volume of the box?

(a)

Let \(x\) represent the length of one side of the square end and \(y\) the length of the longer side. Label these quantities appropriately on the image shown in Figure 56.

(b)

What is the quantity to be optimized in this problem?

1. maximize volume (call this \(V\))

2. maximize the girth plus length (call this \(P\))

3. minimize volume (call this \(V\))

4. minimize the girth plus length (call this \(P\))

(c)

Which formula below represents the quantity you want to optimize in terms of \(x\) and \(y\text{?}\)

1. \(\displaystyle V=x^2y\)

2. \(\displaystyle V=xy^2\)

3. \(\displaystyle P=2x+y\)

4. \(\displaystyle P=4x+y\)

(d)

The problem statement tells us that the parcel's girth plus length (\(P\)) may not exceed 108 inches. In order to maximize volume, we assume that we will actually need the girth plus length \(P\) to equal 108 inches. What equation does this constraint give us involving \(x\) and \(y\text{?}\)

1. \(\displaystyle 108=4x+y\)

2. \(\displaystyle 108 = 2x +y\)

3. \(\displaystyle 108 = x^2 +y\)

4. \(\displaystyle 108 = xy^2\)

(e)

The equation above gives the relationship between \(x\) and \(y\text{.}\) For ease of notation, solve this equation for \(y\) as a function on \(x\) and then find a formula for the volume of the parcel as a function of the single variable \(x\text{.}\) What is the formula for \(V(x)\text{?}\)

1. \(\displaystyle V(x) = x^2 (108-4x)\)

2. \(\displaystyle V(x) = x(108-4x)^2\)

3. \(\displaystyle V(x) =x ^2 (108-2x)\)

4. \(\displaystyle V(x) =x (108-2x)^2\)

(f)

Over what domain should we consider this function? To answer this question, notice that the problem gives us the constraint that \(P\) (girth plus length) is 108 inches. This constraint produces intervals of possible values for \(x\) and \(y\text{.}\)

1. \(\displaystyle 0 \leq x \leq 108 \)

2. \(\displaystyle 0 \leq y \leq 108 \)

3. \(\displaystyle 0 \leq x \leq 27 \)

4. \(\displaystyle 0 \leq y \leq 27 \)

(g)

Use calculus to find the global maximum of the volume of the parcel on the domain you just determined. Justify that you have found the global maximum using either the Closed Interval Method, the First Derivative Test, or the Second Derivative Test!

(a)

If the price of a movie ticket is increased by \(d\) dollars, write a formula for the price \(P\) in terms of \(d\text{.}\)

(b)

If the price of a ticket is increased by one dollar, how many many customers will the theater lose?

(c)

Write a formula for the number of tickets sold \(T\) as a function of a price increase of \(d\) dollars.

(d)

Consider the new price of a ticket \(P(d)\) and the new number of tickets sold \(T(d)\text{.}\) Write a formula for the revenue earned by ticket sales \(R(d)\) as a function of a price increase of \(d\) dollars.

(e)

What is a realistic domain for the function \(R(d)\text{?}\)

(f)

What increase in price \(d\) should the general manager choose to maximize the revenue? What price would a movie ticket cost then and what would the revenue be at that price?

(g)

Suppose now that the cost of running the business when the price is increased by \(d\) dollars is given by \(C(d) = 10d^3 −40d^2 +40d+600\text{.}\) If the manager decides that they will definitely increase the price, what price increase \(d\) maximizes the profit? (Recall that Profit = Revenue - Cost).

(a)

What choice of dimensions will make the rectangular area in the center as large as possible?

(b)

What should the dimensions so the total area enclosed by the running track is maximized?

(a)

Find the coordinates of the point on the curve \(y=\sqrt{x}\) closest to the point \((1,0)\text{.}\)

(b)

The sum of two positive numbers is 48. What is the smallest possible value of the sum of their squares?