Textbook Question
Find a value of θ in the interval [0°, 90°) that satisfies each statement. Give answers in decimal degrees to six decimal places. See Example 2.
cos θ = 0.85536428
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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 2.3.10
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
Verified step by step guidance1
Step 1: Understand the inverse trigonometric function involved. Here, \( \cot^{-1} 30 \) means the angle whose cotangent is 30.
Step 2: Recall the relationship between cotangent and tangent: \( \cot \theta = \frac{1}{\tan \theta} \). So, \( \cot^{-1} 30 = \theta \) implies \( \tan \theta = \frac{1}{30} \).
Step 3: To find the angle \( \theta \), use the inverse tangent function: \( \theta = \tan^{-1} \left( \frac{1}{30} \right) \).
Step 4: Calculate \( \tan^{-1} \left( \frac{1}{30} \right) \) using a calculator or trigonometric tables to find the angle in degrees or radians, depending on the context.
Step 5: Match the calculated angle with the closest approximation given in Column II to complete the pairing.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Inverse Trigonometric Functions
Inverse trigonometric functions, such as cot⁻¹ (arccotangent), are used to find the angle whose trigonometric ratio equals a given value. For example, cot⁻¹(30) gives the angle whose cotangent is 30. Understanding these functions is essential for converting between angle measures and ratio values.
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Introduction to Inverse Trig Functions
Angle Measurement and Approximation
Angles can be measured in degrees or radians and often require approximation for practical use. Matching trigonometric values to their angle approximations involves understanding how to interpret and convert between exact values and decimal approximations, which is crucial for solving problems involving trigonometric functions.
Recommended video:
5:31Reference Angles on the Unit Circle
Trigonometric Ratios and Their Properties
Trigonometric ratios like sine, cosine, tangent, and cotangent relate the angles of a right triangle to the ratios of its sides. Knowing the properties and ranges of these ratios helps in identifying correct angle-value pairs and understanding the behavior of these functions across different quadrants.
Recommended video:
6:04Introduction to Trigonometric Functions
Related Practice
Textbook Question
(Modeling) Fish's View of the World The figure shows a fish's view of the world above the surface of the water. (Data from Walker, J., 'The Amateur Scientist,' Scientific American.) Suppose that a light ray comes from the horizon, enters the water, and strikes the fish's eye. Assume that this ray gives a value of 90° for angle θ₁ in the formula for Snell's law. (In a practical situation, this angle would probably be a little less than 90°.) The speed of light in water is about 2.254 x 10⁸ m per sec. Find angle θ₂ to the nearest tenth.
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Textbook Question
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.
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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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