17.4 CHAPTER 17. TRIGONOMETRY
Step 1 : Determine in which quadrants the solution lies
We look at the sign ofthe trigonometric function. sin θ is given
as a positive amount ( 0 , 3 ). Reference to the CASTdiagram shows
that sine is positive in the first and second quadrants.S A
T C
Step 2 : Determine the reference angle
The small angle θ is the angle returned bythe calculator:sin θ = 0, 3
∴ θ = 17, 46 ◦Step 3 : Determine the generalsolution
Our solution lies in quadrants I and II. We therefore use θ and
180 ◦− θ, and add the (360◦. n) for the periodicity of sine.180 ◦−θ θ
180 ◦+θ 360 ◦−θI : θ = 17, 46 ◦+ (360◦. n); n∈Z
II : θ = 180◦− 17 , 46 ◦+ (360◦. n); n∈Z
= 162, 54 ◦+ (360◦. n); n∈ZThis is called the general solution.Step 4 : Find the specific solutions
We can then find all the values of θ by substituting n =.. .− 1; 0; 1; 2;.. .etc.
For example,
If n = 0, θ = 17, 46 ◦;162, 54 ◦
If n = 1, θ = 377, 46 ◦;522, 54 ◦
If n =− 1 , θ =− 342 , 54 ◦;− 197 , 46 ◦
We can find as many aswe like or find specificsolutions in a given interval by
choosing more values for n.General Solution UsingPeriodicity EMBDI
Up until now we have only solved trigonometricequations where the argument (the bit after the func-
tion, e.g. the θ in cos θ or the (2x−7) in tan(2x−7)), has been θ. If there is anything more complicated
than this we need to bea little more careful.
Let us try to solve tan(2x− 10 ◦) = 2, 5 in the range− 360 ◦≤ x≤ 360 ◦. We want solutions for
positive tangent so using our CAST diagram weknow to look in the 1 stand 3 rdquadrants. Our cal-
culator tells us that 2 x− 10 ◦= 68, 2 ◦. This is our reference angle. So to find the general solution we
proceed as follows:
tan(2x− 10 ◦) = 2, 5
∴ 2 x− 10 ◦ = 68, 2 ◦
I : 2x− 10 ◦ = 68, 2 ◦+ (180◦. n)
2 x = 78, 2 ◦+ (180◦. n)
x = 39, 1 ◦+ (90◦. n); n∈Z