Textbook Question
The radius r of a circle is measured with an error of at most 2%. What is the maximum corresponding percentage error in computing the circle’s
a. circumference?
Ch. 3 - 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 3, Problem 3.6.86a
Temperatures in Fairbanks, Alaska The graph in the accompanying figure shows the average Fahrenheit temperature in Fairbanks, Alaska, during a typical 365-day year. The equation that approximates the temperature on day x is
y = 37 sin[(2π/365)(x − 101)] + 25
and is graphed in the accompanying figure.
a. On what day is the temperature increasing the fastest?
Verified step by step guidance1
Step 1: To determine the day when the temperature is increasing the fastest, we need to find the derivative of the given temperature function y = 37 sin[(2π/365)(x − 101)] + 25. The derivative represents the rate of change of temperature with respect to time (day x).
Step 2: Differentiate the function y with respect to x. Using the chain rule, the derivative of y = 37 sin[(2π/365)(x − 101)] + 25 is given by dy/dx = 37 * cos[(2π/365)(x − 101)] * (2π/365). The constant 25 disappears because its derivative is zero.
Step 3: Simplify the derivative expression to dy/dx = (74π/365) * cos[(2π/365)(x − 101)]. This represents the rate of change of temperature on day x.
Step 4: To find the day when the temperature is increasing the fastest, we need to maximize dy/dx. The cosine function achieves its maximum value of 1 when its argument is zero. Set (2π/365)(x − 101) = 0 and solve for x to find the day.
Step 5: Solve for x: x = 101. This indicates that the temperature is increasing the fastest on day 101 of the year, which corresponds to a date in early April based on the graph.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Derivative and Rate of Change
The derivative of a function at a point gives the rate of change of the function at that point. In the context of the temperature function, the derivative represents how quickly the temperature is changing on a given day. To find when the temperature is increasing the fastest, we need to identify the point where the derivative of the temperature function is at its maximum.
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04:16
Intro To Related Rates
Sine Function and its Properties
The sine function is a periodic function that oscillates between -1 and 1. In the given temperature equation, the sine function models the cyclical nature of temperature changes over the year. Understanding the properties of the sine function, such as its amplitude, period, and phase shift, is crucial for analyzing how the temperature varies throughout the year.
Recommended video:
06:21Properties of Functions
Chain Rule for Differentiation
The chain rule is a fundamental technique in calculus used to differentiate composite functions. In the temperature equation, the sine function is composed with a linear function of x. Applying the chain rule allows us to differentiate the temperature function with respect to x, which is necessary to find the rate of change of temperature and determine when it is increasing the fastest.
Recommended video:
05:02Intro to the Chain Rule
Related Practice
Textbook Question
Tolerance
a. About how accurately must the interior diameter of a 10-m-high cylindrical storage tank be measured to calculate the tank’s volume to within 1% of its true value?
Textbook Question
Find y'' if:
a. y = csc x
Textbook Question
Quadratic approximations
a. Let Q(x) = b₀ + b₁(x − a) + b₂(x − a)² be a quadratic approximation to f(x) at x = a with these properties:
i. Q(a) = f(a)
ii. Q′(a) = f′(a)
iii. Q″(a) = f″(a).
Determine the coefficients b₀, b₁, and b₂.
Textbook Question
Differentiability and Continuity on an Interval
Each figure in Exercises 45–50 shows the graph of a function over a closed interval D. At what domain points does the function appear to be
a. differentiable?
Give reasons for your answers.
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Textbook Question
Differentiability and Continuity on an Interval
Each figure in Exercises 45–50 shows the graph of a function over a closed interval D. At what domain points does the function appear to be
a. differentiable?
Give reasons for your answers.