Textbook Question
Business and Economics
62. Production level Suppose that c(x)=x^3-20x^2 + 20,000x is the cost of manufacturing x items. Find a production level that will minimize the average cost of making x items.
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Ch. 4 - Applications of Derivatives
Hass15th EditionThomas' CalculusISBN: 9780137616077
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Table of contents
- Ch. 1 - Functions155
- Ch. 2 - Limits and Continuity240
- Ch. 3 - Derivatives337
- Ch. 4 - Applications of Derivatives293
- Ch. 5 - Integrals41
- Ch. 6 - Applications of Definite Integrals25
- Ch. 7 - Transcendental Functions489
- Ch. 8 - Techniques of Integration398
- Ch. 9 - First-Order Differential Equations60
- Ch. 10 - Infinite Sequences and Series119
- Ch. 11 - Parametric Equations and Polar Coordinates58
Chapter 4, Problem 4.5.56
56. Airplane landing path An airplane is flying at altitude H when it begins its descent to an airport runway that is at horizontal ground distance L from the airplane, as shown in the accompanying figure. Assume that the landing path of the airplane is the graph of a cubic polynomial function y = ax^3+bx^2+cx+d, where y(-L)= H and y(0)=0.
a. What is dy/dx at x = 0?
b. What is dy/dx at x = -L?
c. Use the values for dy/dx at x = 0 and x =- L together with y(0) = 0 and y(-L) = H to show that y(x)=H[2(x/L)^3+3(x/L)^2]
Verified step by step guidance1
Step 1: Begin by understanding the problem. The airplane's landing path is modeled by a cubic polynomial function y = ax^3 + bx^2 + cx + d. The given conditions are y(-L) = H (altitude at horizontal distance -L) and y(0) = 0 (altitude at the airport). Additionally, dy/dx at x = 0 and x = -L are required to derive the specific form of the polynomial.
Step 2: To find dy/dx at x = 0, differentiate the polynomial y = ax^3 + bx^2 + cx + d with respect to x. The derivative is dy/dx = 3ax^2 + 2bx + c. Substitute x = 0 into this derivative to find dy/dx at x = 0, which simplifies to c.
Step 3: To find dy/dx at x = -L, use the same derivative dy/dx = 3ax^2 + 2bx + c. Substitute x = -L into this derivative to find dy/dx at x = -L, which simplifies to 3a(-L)^2 + 2b(-L) + c.
Step 4: Use the boundary conditions y(-L) = H and y(0) = 0 to solve for d and relate the coefficients a, b, c, and d. Substituting x = -L into y = ax^3 + bx^2 + cx + d gives H = a(-L)^3 + b(-L)^2 + c(-L) + d. Substituting x = 0 into y = ax^3 + bx^2 + cx + d gives 0 = d.
Step 5: Combine the results for dy/dx at x = 0 and x = -L, along with the boundary conditions y(-L) = H and y(0) = 0, to derive the specific form of the polynomial. After simplification, the landing path is shown to be y(x) = H[2(x/L)^3 + 3(x/L)^2].
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Cubic Polynomial Functions
A cubic polynomial function is a mathematical expression of the form y = ax^3 + bx^2 + cx + d, where a, b, c, and d are constants. This type of function can model various real-world scenarios, including the trajectory of an airplane during landing. Understanding the properties of cubic functions, such as their shape and critical points, is essential for analyzing the landing path described in the question.
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Derivative and Slope
The derivative of a function, denoted as dy/dx, represents the slope of the tangent line to the curve at a given point. In the context of the airplane's landing path, calculating dy/dx at specific points (x = 0 and x = -L) provides insight into the rate of change of altitude as the airplane descends. This information is crucial for understanding the airplane's approach angle and descent rate.
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Boundary Conditions
Boundary conditions are specific values that a function must satisfy at certain points. In this problem, the conditions y(-L) = H and y(0) = 0 define the altitude of the airplane at the start and end of its descent. These conditions are essential for determining the coefficients of the cubic polynomial and for deriving the final expression for y(x), ensuring that the function accurately represents the airplane's landing path.
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Related Practice
Textbook Question
Checking the Mean Value Theorem
Which of the functions in Exercises 7–12 satisfy the hypotheses of the Mean Value Theorem on the given interval, and which do not? Give reasons for your answers.
f(x) = {x² − x, −2 ≤ x ≤−1
2x² − 3x − 3, −1 < x ≤ 0
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Textbook Question
Absolute Extrema on Finite Closed Intervals
In Exercises 21–36, find the absolute maximum and minimum values of each function on the given interval. Then graph the function. Identify the points on the graph where the absolute extrema occur, and include their coordinates.
g(x) = √(4 − x²), −2 ≤ x ≤ 1
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Textbook Question
The 8-ft wall shown here stands 27 ft from the building. Find the length of the shortest straight beam that will reach to the side of the building from the ground outside the wall.
211
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Textbook Question
Checking Antiderivative Formulas
Verify the formulas in Exercises 57–62 by differentiation.
∫csc²((x − 1)/3)dx = −3cot((x − 1)/3) + C
37
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Textbook Question
Identifying Extrema
In Exercises 19–40:
a. Find the open intervals on which the function is increasing and those on which it is decreasing.
b. Identify the function’s local extreme values, if any, saying where they occur.
g(x) = x√8 − x²
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