🔺Trigonometry Unit 5 – Graphs of Other Trigonometric Functions
Trigonometric functions go beyond sine and cosine. This unit explores graphs of tangent, cotangent, secant, and cosecant functions. We'll learn about their unique properties, including periods, amplitudes, and asymptotes.
Understanding these graphs is crucial for modeling real-world phenomena. We'll dive into transformations of trigonometric functions, applying shifts and stretches to create more complex models. This knowledge forms the foundation for advanced applications in physics, engineering, and more.
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Key Concepts and Definitions
Trigonometric functions include sine, cosine, tangent, cotangent, secant, and cosecant, which are defined in terms of angles and ratios of sides in a right triangle
Period of a trigonometric function represents the length of one complete cycle on the graph, with sine and cosine having a period of 2π, while tangent and cotangent have a period of π
Amplitude of a trigonometric function measures the height of the graph from the midline to the maximum or minimum point, with the parent functions having an amplitude of 1
Phase shift of a trigonometric function moves the graph horizontally, with a positive phase shift moving the graph to the left and a negative phase shift moving it to the right
Vertical shift of a trigonometric function moves the graph up or down, with a positive vertical shift moving the graph up and a negative vertical shift moving it down
Asymptotes are vertical lines that the graph of a function approaches but never touches, occurring in tangent, cotangent, secant, and cosecant functions
Tangent and cotangent functions have asymptotes at x=2π+πk and x=πk, respectively, where k is an integer
Secant and cosecant functions have asymptotes at x=2π+πk and x=πk, respectively, where k is an integer
Graphing Cosine Functions
The cosine function, denoted as cos(x), is defined as the ratio of the adjacent side to the hypotenuse in a right triangle
The parent function of cosine is f(x)=cos(x), which has a domain of all real numbers and a range of [−1,1]
The graph of the cosine function is a smooth, continuous wave that oscillates between -1 and 1, with a period of 2π
The cosine function has maximum points at x=2πk and minimum points at x=π+2πk, where k is an integer
The cosine function is an even function, meaning that cos(−x)=cos(x) for all x in the domain
To graph a cosine function with a phase shift, vertical shift, or amplitude change, use the general form f(x)=Acos(B(x−C))+D, where:
A represents the amplitude (vertical stretch or compression)
B represents the period (horizontal stretch or compression)
C represents the phase shift (horizontal shift)
D represents the vertical shift
Graphing Tangent Functions
The tangent function, denoted as tan(x), is defined as the ratio of the opposite side to the adjacent side in a right triangle
The parent function of tangent is f(x)=tan(x), which has a domain of all real numbers except x=2π+πk, where k is an integer, and a range of all real numbers
The graph of the tangent function consists of repeated S-shaped curves with asymptotes at x=2π+πk, where k is an integer
The tangent function has a period of π, meaning that the graph repeats itself every π units
The tangent function is an odd function, meaning that tan(−x)=−tan(x) for all x in the domain
To graph a tangent function with a phase shift or vertical stretch, use the general form f(x)=Atan(B(x−C)), where:
A represents the vertical stretch
B represents the period (horizontal stretch or compression)
C represents the phase shift (horizontal shift)
Graphing Cotangent Functions
The cotangent function, denoted as cot(x), is defined as the reciprocal of the tangent function, or the ratio of the adjacent side to the opposite side in a right triangle
The parent function of cotangent is f(x)=cot(x), which has a domain of all real numbers except x=πk, where k is an integer, and a range of all real numbers
The graph of the cotangent function consists of repeated U-shaped curves with asymptotes at x=πk, where k is an integer
The cotangent function has a period of π, meaning that the graph repeats itself every π units
The cotangent function is an odd function, meaning that cot(−x)=−cot(x) for all x in the domain
To graph a cotangent function with a phase shift or vertical stretch, use the general form f(x)=Acot(B(x−C)), where:
A represents the vertical stretch
B represents the period (horizontal stretch or compression)
C represents the phase shift (horizontal shift)
Graphing Secant and Cosecant Functions
The secant function, denoted as sec(x), is defined as the reciprocal of the cosine function, or the ratio of the hypotenuse to the adjacent side in a right triangle
The cosecant function, denoted as csc(x), is defined as the reciprocal of the sine function, or the ratio of the hypotenuse to the opposite side in a right triangle
The parent function of secant is f(x)=sec(x), which has a domain of all real numbers except x=2π+πk, where k is an integer, and a range of (−∞,−1]∪[1,∞)
The parent function of cosecant is f(x)=csc(x), which has a domain of all real numbers except x=πk, where k is an integer, and a range of (−∞,−1]∪[1,∞)
The graph of the secant function consists of repeated U-shaped curves with asymptotes at x=2π+πk, where k is an integer
The graph of the cosecant function consists of repeated U-shaped curves with asymptotes at x=πk, where k is an integer
Both secant and cosecant functions have a period of 2π, meaning that the graph repeats itself every 2π units
To graph a secant or cosecant function with a phase shift or vertical stretch, use the general forms f(x)=Asec(B(x−C)) or f(x)=Acsc(B(x−C)), where:
A represents the vertical stretch
B represents the period (horizontal stretch or compression)
C represents the phase shift (horizontal shift)
Transformations of Trigonometric Graphs
Transformations of trigonometric graphs include changes in amplitude, period, phase shift, and vertical shift
Amplitude changes affect the height of the graph, with a vertical stretch occurring when ∣A∣>1 and a vertical compression occurring when 0<∣A∣<1
Period changes affect the length of one complete cycle, with a horizontal compression occurring when ∣B∣>1 and a horizontal stretch occurring when 0<∣B∣<1
Phase shifts move the graph horizontally, with a positive phase shift (C>0) moving the graph to the left and a negative phase shift (C<0) moving the graph to the right
Vertical shifts move the graph up or down, with a positive vertical shift (D>0) moving the graph up and a negative vertical shift (D<0) moving the graph down
To apply multiple transformations, follow the order: amplitude change, period change, phase shift, and then vertical shift
When given an equation in the form f(x)=Asin(B(x−C))+D or f(x)=Acos(B(x−C))+D, identify the values of A, B, C, and D to determine the transformations applied to the parent function
Applications and Real-World Examples
Trigonometric functions have numerous applications in various fields, such as physics, engineering, and music
In physics, trigonometric functions are used to model periodic phenomena, such as waves, oscillations, and rotations
Example: The motion of a pendulum can be modeled using the sine function, with the angle of the pendulum varying sinusoidally over time
In engineering, trigonometric functions are used to analyze and design structures, such as bridges and buildings, by calculating angles, distances, and forces
Example: The height of a suspension bridge's cable at any point can be modeled using a cosine function, with the lowest point of the cable at the center of the bridge
In music, trigonometric functions are used to describe the harmonics and waveforms of musical notes and instruments
Example: The sound waves produced by a guitar string can be modeled using a combination of sine functions with different frequencies and amplitudes
Trigonometric functions are also used in navigation and GPS systems to calculate distances and angles between locations on the Earth's surface
Example: The great-circle distance between two points on the Earth's surface can be calculated using the haversine formula, which involves the sine function
Common Mistakes and How to Avoid Them
Confusing the period of tangent and cotangent functions (π) with the period of sine, cosine, secant, and cosecant functions (2π)
Remember that tangent and cotangent functions have asymptotes that occur twice as frequently as those of secant and cosecant functions
Incorrectly applying transformations to trigonometric functions, especially when multiple transformations are involved
Follow the order of transformations: amplitude change, period change, phase shift, and then vertical shift
Forgetting to consider the domain restrictions when graphing tangent, cotangent, secant, and cosecant functions
Identify the asymptotes and exclude them from the domain
Misinterpreting the signs of the phase shift and vertical shift in the general form of the equation
A positive phase shift (C>0) moves the graph to the left, while a negative phase shift (C<0) moves the graph to the right
A positive vertical shift (D>0) moves the graph up, while a negative vertical shift (D<0) moves the graph down
Neglecting to consider the amplitude and period changes when sketching the graph of a transformed trigonometric function
Pay attention to the coefficients A and B in the general form of the equation to determine the amplitude and period changes
Incorrectly identifying the period of a transformed trigonometric function
The period of a transformed function is given by ∣B∣2π, where B is the coefficient of the input angle in the general form of the equation