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Splash Screen. Five-Minute Check (over Lesson 4-4) Then/Now New Vocabulary Key Concept: Properties of the Tangent Function Key Concept: Period of the Tangent Function Example 1: Graph Horizontal Dilations of the Tangent Function
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Five-Minute Check (over Lesson 4-4) Then/Now New Vocabulary Key Concept: Properties of the Tangent Function Key Concept: Period of the Tangent Function Example 1: Graph Horizontal Dilations of the Tangent Function Example 2: Graph Reflections and Translations of the Tangent Function Key Concept: Properties of the Cotangent Function Example 3: Sketch the Graph of a Cotangent Function Key Concept: Properties of the Cosecant and Secant Functions Example 4: Sketch Graphs of Cosecant and Secant Functions Example 5: Sketch Damped Trigonometric Functions Key Concept: Damped Harmonic Motion Example 6: Real-World Example: Damped Harmonic Motion Lesson Menu
A. Describe how the graphs of f(x) = sin x andg(x) = 2 sin x are related. Then find the amplitudeand period of g(x). A.The graph of g(x) is the graph of f(x) expanded horizontally. amplitude = 2, period = 24. B.The graph of g(x) is the graph of f(x) compressed horizontally. amplitude = 1, period = π. C.The graph of g(x) is the graph of f(x) expanded vertically. amplitude = 2, period = 2π. D.The graph of g(x) is the graph of f(x) compressed vertically. amplitude = 0.5, period = 2π. 5–Minute Check 1
A. B. C. D. B. Sketch the graphs of f(x) = sin x andg(x) = 2 sin x on the same coordinate axes. 5–Minute Check 1
A. State the amplitude, period, frequency, phaseshift, and vertical shift of A.amplitude = 2; period = 2π; frequency = ; phase shift = B.amplitude = 1; period = π; frequency = ; phase shift = C.amplitude = 2; period = 2π; frequency = ; phase shift = ; D.amplitude = period = ; frequency = ; phase shift = 5–Minute Check 2
B. Graph two periods of A. B. C. D. 5–Minute Check 2
Write a sinusoidal function that can be used tomodel the initial behavior of a sound wave witha frequency of 820 hertz and an amplitude of 0.35. A.y = 0.35 sin 820t B.y = 0.35 sin 410πt C.y = 0.35 sin 820πt D.y = 0.35 sin 1640πt 5–Minute Check 3
You analyzed graphs of trigonometric functions. (Lesson 4-4) • Graph tangent and reciprocal trigonometric functions. • Graph damped trigonometric functions. Then/Now
damped trigonometric function • damping factor • damped oscillation • damped wave • damped harmonic motion Vocabulary
Locate the vertical asymptotes, and sketch the graph of y = tan . The graph of y = tan is the graph of y = tan x expanded horizontally. The period is or 3. Find two consecutive vertical asymptotes by solving bx + c = – and bx + c = . Graph Horizontal Dilations of the Tangent Function Example 1
Create a table listing key points, including the x-intercept, that are located between the two vertical asymptotes at Graph Horizontal Dilations of the Tangent Function Example 1
Sketch the curve through the indicated key points for the function. Then sketch one cycle to the left on and one cycle to the right on . Graph Horizontal Dilations of the Tangent Function Example 1
Graph Horizontal Dilations of the Tangent Function Answer: Example 1
A. vertical asymptotes: , n is an odd integer B. vertical asymptotes: , n is an odd integer C. vertical asymptotes: , n is an integer D. vertical asymptotes: , n is an odd integer A. Locate the vertical asymptotes of y = tan 4x. Example 1
A. B. C. D. B. Sketch the graph of y = tan 4x. Example 1
A. Locate the vertical asymptotes, and sketch the graph of . The graph of y = –tan is the graph of y = tan x expanded horizontally and then reflected in the x-axis. The period is . Find two consecutive vertical asymptotes. Graph Reflections and Translations of the Tangent Function Example 2
Multiply. Graph Reflections and Translations of the Tangent Function Create a table listing key points, including the x-intercept, that are located between the two vertical asymptotes at x = –2 and x = 2. Example 2
Graph Reflections and Translations of the Tangent Function Sketch the curve through the indicated key points for the function. Then repeat the pattern for one cycle to the left and right of the first curve. Answer: Example 2
B. Locate the vertical asymptotes, and sketch the graph of . The graph of y = –tan is the graph of y = tan x shifted to the left and then reflected in the x-axis. The period is or π. Find two consecutive vertical asymptotes. Graph Reflections and Translations of the Tangent Function Example 2
Subtract. Graph Reflections and Translations of the Tangent Function Create a table listing key points, including the x-intercept, that are located between the two vertical asymptotes at x = – and x = 0. Example 2
Graph Reflections and Translations of the Tangent Function Sketch the curve through the indicated key points for the function. Then sketch one cycle to the left and right. Answer: Example 2
A. vertical asymptotes: n is an odd integer B. vertical asymptotes: n is an integer C. vertical asymptotes: n is an odd integer D. vertical asymptotes: n is an integer Locate the vertical asymptotes of the graph of y = – tan(3x + π). Example 2
The graph of y = cot 2x is the graph of y = cot x compressed horizontally. The period is or . Find two consecutive vertical asymptotes. x = 0 Simplify. x = Sketch the Graph of a Cotangent Function Locate the vertical asymptotes, and sketch the graph of y = cot 2x. 2x + 0 = 0 b = 2, c = 0 2x + 0 = Example 3
Create a table listing key points, including the x-intercept, that are located between the two vertical asymptotes at x = 0 and x = . Sketch the Graph of a Cotangent Function Example 3
Sketch the Graph of a Cotangent Function Following the same guidelines that you used for the tangent function, sketch the curve through the indicated key points that you found. Then sketch one cycle to the left and right of the first curve. Answer: Example 3
A. Locate the vertical asymptotes of A. vertical asymptotes: n is an odd integer B. vertical asymptotes: n is an integer C. vertical asymptotes: x = nπ,n is an odd integer D. vertical asymptotes: x = nπ,n is an integer Example 3
B. Sketch the graph of A. B. C. D. Example 3
The graph of y = –sec 2x is the graph of y = sec x compressed horizontally and then reflected in the x-axis. The period is or . Two vertical asymptotes occur when bx + c = and bx + c = . Therefore, two asymptotes are 2x + 0 = or x = – and 2x + 0 = or x = . Sketch Graphs of Cosecant and Secant Functions A. Locate the vertical asymptotes, and sketch the graph of y = –sec 2x . Example 4
Create a table listing key points that are located between the asymptotes at x = and x = . Sketch Graphs of Cosecant and Secant Functions Example 4
Sketch Graphs of Cosecant and Secant Functions Graph one cycle on the interval. Then sketch one cycle to the left and right. Answer: Example 4
B. Locate the vertical asymptotes, and sketch the graph of . The graph of y = csc is the graph of y = csc x shifted units to the left. The period is or 2. Two vertical asymptotes occur when bx + c = – and bx + c = . Therefore, two asymptotes are x + = – or x = and x + = or x = . Sketch Graphs of Cosecant and Secant Functions Example 4
Create a table listing key points, including the relative maximum and minimum, that are located between the two vertical asymptotes at x = and x = . Sketch Graphs of Cosecant and Secant Functions Example 4
Sketch Graphs of Cosecant and Secant Functions Sketch the curve through the indicated key points for the function. Then sketch one cycle to the left and right. Answer: Example 4
A. Locate the vertical asymptotes of y = csc A. x = nπ,n is an odd integer B. n is an integer C. n is an odd integer D. x = nπ,n is an integer Example 4
B. Sketch the graph of y = csc A. B. C. D. Example 4
A. Identify the damping factor f(x) of . Then use a graphing calculator to sketch the graphs of f(x), –f(x), and the given function in the same viewing window. Describe the behavior of the graph. The function y = is the product of the functions y = and y = sin x, so f(x) = . Sketch Damped Trigonometric Functions Example 5
Sketch Damped Trigonometric Functions The amplitude of the function is decreasing as x approaches 0 from both directions. Example 5
Answer:f(x) = ; The amplitude is decreasing as x approaches 0 from both directions. Sketch Damped Trigonometric Functions Example 5
Sketch Damped Trigonometric Functions B. Identify the damping factor f(x) of y = x2 cos3x. Then use a graphing calculator to sketch the graphs of f(x), –f(x), and the given function in the same viewing window. Describe the behavior of the graph. The function y = x2 cos 3x is the product of the functions y = x2 and y = cos 3x. Therefore, the damping factor is f(x) = x2. The amplitude is decreasing as x approaches 0 from both directions. Example 5
Sketch Damped Trigonometric Functions Answer:f(x) = x2; The amplitude is decreasing as x approaches 0 from both directions. Example 5
A. f(x) = 4x B. f(x) = C. f(x) = sin x D. f(x) = 4x sin x Identify the damping factor f(x) of y = 4x sin x. Example 5
Damped Harmonic Motion A. MUSIC A guitar string is plucked at a distance of 0.95 centimeter above its rest position, then released, causing a vibration. The damping constant for the string is 1.3, and the note produced has a frequency of 200 cycles per second. Write a trigonometric function that models the motion of the string. The maximum displacement of the string occurs when t = 0, so y = ke–ct cos t can be used to model the motion of the string because the graph of y = cos wt has a y-intercept other than 0. Example 6
= frequency Multiply each side by 2π. Damped Harmonic Motion The maximum displacement occurs when the string is plucked 0.95 centimeter. The total displacement is the maximum displacement M minus the minimum displacement m, so k = M – m = 0.95 – 0 or 0.95 cm. You can use the value of the frequency to find w. Example 6
Damped Harmonic Motion Write a function using the values of k, w, and c. y = 0.95e–1.3t cos 400πt is one model that describes the motion of the string. Sample Answer:y = 0.95e–1.3t cos 400πt Example 6
Damped Harmonic Motion B. MUSIC A guitar string is plucked at a distance of 0.95 centimeter above its rest position, then released, causing a vibration. The damping constant for the string is 1.3, and the note produced has a frequency of 200 cycles per second. Determine the amount of time t that it takes the string to be damped so that –0.38 ≤ y ≤ 0.38. Use a graphing calculator to determine the value of t when the graph of y = 0.95e–1.3t cos 400πt is oscillating between y = –0.38 and y = 0.38. Example 6