Textbook Question
Use a calculator to approximate the value of each expression. Give answers to six decimal places. In Exercises 21–28, simplify the expression before using the calculator. See Example 1.
1/ sec 14.8°
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Ch. 2 - Acute Angles and Right Triangles
Lial12th EditionTrigonometryISBN: 9780136552161
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Table of contents
- Ch. R - Algebra Review381
- Ch. 1 - Trigonometric Functions188
- Ch. 2 - Acute Angles and Right Triangles168
- Ch. 3 - Radian Measure and The Unit Circle155
- Ch. 4 - Graphs of the Circular Functions100
- Ch. 5 - Trigonometric Identities238
- Ch. 6 - Inverse Circular Functions and Trigonometric Equations158
- Ch. 7 - Applications of Trigonometry and Vectors148
- Ch. 8 - Complex Numbers, Polar Equations, and Parametric Equations15
Chapter 3, Problem 2.5.30
Solve each problem. See Examples 1 and 2. Distance between Two Cities The bearing from Atlanta to Macon is S 27° E, and the bearing from Macon to Augusta is N 63° E. An automobile traveling at 62 mph needs 1¼ hr to go from Atlanta to Macon and 1¾ hr to go from Macon to Augusta. Find the distance from Atlanta to Augusta.
Verified step by step guidance1
Identify the distances traveled from Atlanta to Macon and from Macon to Augusta using the formula \(\text{distance} = \text{speed} \times \text{time}\). For Atlanta to Macon, calculate \(d_1 = 62 \times 1.25\), and for Macon to Augusta, calculate \(d_2 = 62 \times 1.75\).
Draw a diagram representing the positions of Atlanta, Macon, and Augusta, including the bearings. The bearing from Atlanta to Macon is \(S 27^\circ E\), which means starting from south, rotate 27 degrees towards east. The bearing from Macon to Augusta is \(N 63^\circ E\), starting from north, rotate 63 degrees towards east.
Determine the angle between the two paths (Atlanta to Macon and Macon to Augusta) at point Macon. Since the bearings are given relative to the cardinal directions, find the interior angle between the two directions by adding or subtracting the given angles appropriately.
Use the Law of Cosines to find the distance from Atlanta to Augusta. Label the triangle with sides \(d_1\), \(d_2\), and the unknown side \(d\), and the included angle \(\theta\) found in the previous step. The Law of Cosines formula is: \(d^2 = d_1^2 + d_2^2 - 2 d_1 d_2 \cos(\theta)\).
Solve for \(d\) by taking the square root of both sides: \(d = \sqrt{d_1^2 + d_2^2 - 2 d_1 d_2 \cos(\theta)}\). This will give the distance from Atlanta to Augusta.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Bearing and Direction in Navigation
Bearing is a way to describe direction using angles relative to the cardinal points (N, S, E, W). For example, S 27° E means starting from south and rotating 27° towards east. Understanding how to interpret and convert these bearings into angles for calculations is essential for solving navigation problems.
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Finding Direction of a Vector
Distance, Speed, and Time Relationship
The relationship between distance, speed, and time is given by the formula distance = speed × time. Knowing the speed and travel time allows calculation of the distance between two points, which is crucial for determining the lengths of segments in the problem.
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4:56Example 1
Law of Cosines for Non-Right Triangles
The Law of Cosines relates the lengths of sides of any triangle to the cosine of one of its angles. It is used to find an unknown side when two sides and the included angle are known, which is necessary here to find the distance between Atlanta and Augusta given the bearings and distances.
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Related Practice
Textbook Question
CONCEPT PREVIEW Match each trigonometric function value or angle in Column I with its appropriate approximation in Column II.
Column I: 1.
cot⁻¹ 30
Column II:
A. 88.09084757°
B. 63.25631605°
C. 1.909152433°
D. 17.45760312°
E. 0.2867453858
F. 1.962610506
G. 14.47751219°
H. 1.015426612
I. 1.051462224
J. 0.9925461516
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Textbook Question
Concept Check The two methods of expressing bearing can be interpreted using a rectangular coordinate system. Suppose that an observer for a radar station is located at the origin of a coordinate system. Find the bearing of an airplane located at each point. Express the bearing using both methods. (0, -2)
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Textbook Question
Find two angles in the interval [0°, 360°) that satisfy each of the following. Round answers to the nearest degree. cos θ = 0.10452846
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Textbook Question
Use a calculator to approximate the value of each expression. Give answers to six decimal places. In Exercises 21–28, simplify the expression before using the calculator. See Example 1.
sin 38° 42'
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Textbook Question
Find two angles in the interval [0°, 360°) that satisfy each of the following. Round answers to the nearest degree. sin θ = 0.52991926
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