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Download 6.1.1 Solving Trig Equations
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6.1.1 SOLVING TRIG EQUATIONS FRIDAY, FEBRUARY 13, 2015 INTRODUCTION • You can already solve all kinds of equations. You have been doing it since your first algebra class. • You know that some equations have no solutions, some have only one solution, and others can have any number of solutions, even an infinite number. x=x+1 x+1=x+1 5=x+1 INTRODUCTION • Today’s lesson focuses on solving trigonometric equations (which we will refer to as trig equations from now on). • The concepts and the procedures you will use are basically the same, but there are a few unique qualities of trig equations that you have to keep in mind. • Let’s see what sets this kind of solving apart from the rest. • 6-1. We begin with the graphs of y = sin x and y = 12 shown below. For now, concentrate on the portion of the graph shown, 0 ≤ x ≤ 2π . • How do you know that the equation, sin x = 12 has more than one solution? • What are the solutions for sin x = 12 , where 0 ≤ x ≤ 2π ? 6.1 CONTINUED • Now recall the unit circle. The horizontal line y = 12 has been drawn across the circle. Explain how this can help to find solutions to the equation sin x = 12 for 0 ≤ x ≤ 2π . 6.1 CONTINUED • Using both the graph and the unit circle, we want to solve the equation sin x = − 23 . • How? • 6-2. What about cos x = 12 over the same interval, 0 ≤ x ≤ 2π ? Draw a line on the unit circle so that you can find where the x-coordinate equals. What angles satisfy the equation? CLOSURE • Solving a trigonometric equation is like solving any equation: our goal is to get the variable by itself on one side of the equal sign. • We want to find out what values of the variable will make the equation “true.” • But, we need to keep in mind when solving trig equations, that there are not necessarily a finite number of solutions. • The solutions we want will depend on the problem situation. • If only a few solutions are required, we can limit the domain to a particular interval. MATH NOTES - SOLVING PERIODIC FUNCTIONS • When solving periodic functions (such as sin x = − 22 ), we get an infinite number of solutions (or no solution). • In the example sin x = − 22 , we get the solutions: 5𝜋 13𝜋 𝜋 7𝜋 15𝜋 x = … −3𝜋 , , … and x = … − , , 4 … 4 4 4 4 4 • This may be written more compactly as x = 5𝜋 + 2πn, 4 7𝜋 + 2πn, where n is any integer. 4 • If we restrict the domain to [0, 2π ), we get only two 7𝜋 solutions: x = 5𝜋 and . 4 4
