Trigonometric equations of the form acosθ+bsinθ=c, where a, b, and c are real numbers, can be solved by using t-formulae or by expressing it in the form of Rcos(θ±α)=c or Rsin(θ±α)=c.
Using t-formulae
Recall the double angle formulae:
sin2x=2sinxcosx
cos2x=cos2x−sin2x
Both equations for sin2x and cos2x can be expressed in terms of tan2θ.
Now, let θ=2x, then x=2θ, equation (7.7) becomes:
sinθ=1+tan22θ2tan2θ
Let t=tan2θ, then sinθ=1+t22t. This is called the t-formula for sinθ.
Example 1
Solve the equation 5cosθ−2sinθ=2 for 0∘≤θ≤360∘ by using the substitution t=tan2θ.
Solution:
Substituting the t-formulae into the equation:
5(1+t21−t2)−2(1+t22t)=2
5(1−t2)−4t=2(1+t2)
5−5t2−4t=2+2t2
7t2+4t−3=0
(7t−3)(t+1)=0
t=73 or t=−1
If t=73, tan2θ=73, so 2θ≈23.2∘, and θ≈46.4∘ or 180∘+46.4∘=226.4∘
If t=−1, tan2θ=−1, so 2θ=−45∘ or 135∘, and θ=−90∘ or 270∘.
Therefore, the solutions for 0∘≤θ≤360∘ are approximately 46.4∘ and 270∘.
Expressing acosθ+bsinθ in the form Rcos(θ±α) or Rsin(θ±α)
The technique of expressing acosθ+bsinθ in the form of Rcos(θ±α) or Rsin(θ±α) is useful in finding maximum and minimum values of trigonometric equations of the form acosθ+bsinθ=c.
Expressing acosθ+bsinθ in the form of Rcos(θ−α)
Using the compound angle formula for Rcos(θ−α) gives:
Rcos(θ−α)≡acosθ+bsinθ≡Rcosθcosα+Rsinθsinα
Comparing the coefficients of cosθ gives:
a=Rcosα ………………………………………… (i)
Comparing the coefficients of sinθ gives:
b=Rsinα ………………………………………… (ii)
Squaring and adding equations (i) and (ii) gives:
a2+b2=R2cos2α+R2sin2α
a2+b2=R2(cos2α+sin2α)
R2=a2+b2
R=a2+b2 (where R is positive)
The value of α is obtained by dividing equation (ii) by equation (i):
tanα=RcosαRsinα=ab
α=tan−1(ab)
Example 2
Express 3cosθ−4sinθ in the form of Rcos(θ−α).
Solution:
Let 3cosθ−4sinθ=Rcos(θ−α)=Rcosθcosα+Rsinθsinα
Comparing coefficients:
Rcosα=3
Rsinα=−4
R=32+(−4)2=25=5
tanα=3−4
α=tan−1(3−4)≈−53.1∘ (or 306.9°)
Therefore, 3cosθ−4sinθ=5cos(θ+53.1∘).
Example 3
Show that 5cosθ−12sinθ can be expressed in the form 13cos(θ+67.4∘).
Solution:
Let 5cosθ−12sinθ=Rcos(θ+α)
Comparing coefficients:
Rcosα=5
Rsinα=−12
R=52+(−12)2=169=13
tanα=5−12
α≈−67.4∘ (or 292.6°)
Therefore, 5cosθ−12sinθ=13cos(θ+67.4∘).
Expressing acosθ+bsinθ in the form Rsin(θ+α)
Using the compound angle formula for Rsin(θ+α) gives:
acosθ+bsinθ=R(sinθcosα+cosθsinα)
Comparing coefficients:
b=Rcosα ………………………………………… (i)
a=Rsinα ………………………………………… (ii)
Squaring and adding equations (i) and (ii) gives:
a2+b2=R2
R=a2+b2
Dividing equation (ii) by equation (i) gives:
tanα=ba
α=tan−1(ba)
Example 4
Express 7cosθ+24sinθ in the form of Rsin(θ+α).
Solution:
Let 7cosθ+24sinθ=Rsin(θ+α)
Comparing coefficients:
Rcosα=24
Rsinα=7
R=72+242=25
tanα=247
α≈16.3∘
Therefore, 7cosθ+24sinθ=25sin(θ+16.3∘).
Example 5
Find the maximum and minimum values of 24sinθ−7cosθ, stating the values of θ for which the maximum and minimum values are attained.
Solution:
Let 24sinθ−7cosθ=Rsin(θ−α)
R=242+(−7)2=576+49=625=25
tanα=24−7
α≈−16.3∘
So, 24sinθ−7cosθ=25sin(θ+16.3∘)
Since −1≤sin(θ+16.3∘)≤1, the maximum value is 25 (when sin(θ+16.3∘)=1) and the minimum value is -25 (when sin(θ+16.3∘)=−1).
For the maximum value:
sin(θ+16.3∘)=1
θ+16.3∘=90∘
θ=73.7∘
For the minimum value:
sin(θ+16.3∘)=−1
θ+16.3∘=270∘
θ=253.7∘
Therefore, the maximum value is 25 at θ=73.7∘, and the minimum value is -25 at θ=253.7∘.
Example 6
Show that 13cosλ+7sinλ can be expressed in the form 218cos(λ−α), where tanα=137. Hence, find the maximum and minimum values of the function, giving the corresponding values of λ.
Solution:
Let 13cosλ+7sinλ=Rcos(λ−α)
R=132+72=169+49=218
tanα=137
α≈28.3∘
So, 13cosλ+7sinλ=218cos(λ−28.3∘)
The maximum value is 218 (when cos(λ−28.3∘)=1), and the minimum value is −218 (when cos(λ−28.3∘)=−1).
For the maximum value:
λ−28.3∘=0∘
λ=28.3∘
For the minimum value:
λ−28.3∘=180∘
λ=208.3∘
Example 7
Solve the equation 52=4cos2x+3sin2x for values in the interval −180∘≤x≤180∘.
Solution:
Let 4cos2x+3sin2x=Rsin(2x+α)
R=42+32=5
tanα=34
α≈53.1∘
So, 52=5sin(2x+53.1∘)
sin(2x+53.1∘)=2
Since the maximum value of sine is 1, and 2>1, there are no solutions to this equation.
Example 8
Solve the equation 3cosx+sinx=2 for 0∘≤x≤360∘.
Solution:
Let 3cosx+sinx=Rcos(x−α)
R=32+12=10
tanα=31
α≈18.4∘
So, 10cos(x−18.4∘)=2
cos(x−18.4∘)=102
x−18.4∘≈±50.8∘
x≈69.2∘ or x≈−32.4∘+360∘=327.6∘
Therefore, the solutions are approximately x=69.2∘ and 327.6∘.
General solutions of trigonometric equations
A general solution is a solution that contains all possible solutions of a given trigonometric equation.
Consider the graph of the straight lines y=a, where −1≤a≤1, and y=cosθ as shown in Figure 7.5:
The principal value of the equation cosθ=a is α=cos−1a. Since the cosine function is periodic with a period of 360∘ or 2π radians, other solutions are obtained by adding or subtracting multiples of 360∘ or 2π to ±α.
The general solution of the equation cosθ=a where −1≤a≤1 is given as:
In degrees: θ=±α+360∘n, where α=cos−1a and n is an integer.
In radians: θ=±α+2πn, where α=cos−1a and n is an integer.
Similarly, the general solutions for sine and tangent are:
In degrees:
If sinθ=sinα, then θ=n180∘+(−1)nα
If tanθ=tanα, then θ=α+180∘n
In radians:
If sinθ=sinα, then θ=nπ+(−1)nα
If tanθ=tanα, then θ=α+nπ
where n is an integer.
Example 1
Find the general solution of the equation cosx+sinx=1, giving your answer in terms of π.
Solution:
Express cosx+sinx in the form Rcos(x−α):
R=12+12=2
tanα=11=1, so α=4π
The equation becomes: 2cos(x−4π)=1
cos(x−4π)=21
x−4π=±4π+2nπ
Case 1: x−4π=4π+2nπ
x=2π+2nπ
Case 2: x−4π=−4π+2nπ
x=2nπ
Therefore, the general solutions are x=2π+2nπ and x=2nπ, where n is an integer.
Example 2
Find the general solution of the equation cotx+cscx=3, giving the answer in terms of π.
Solution:
sinxcosx+sinx1=3
cosx+1=3sinx
3sinx−cosx=1
Express 3sinx−cosx in the form Rsin(x−α):
R=(3)2+(−1)2=3+1=2
tanα=3−1, so α=−6π or 65π. Using the positive value is easier for this example.
The equation becomes: 2sin(x−65π)=1
sin(x−65π)=21
x−65π=nπ+(−1)n6π
x=nπ+(−1)n6π+65π
Example 3
Use the t-formulae to find the general solution of the equation 2cosx−sinx=1, giving the answers in radians.
Solution:
Using the t-formulae, where t=tan2x:
2(1+t21−t2)−1+t22t=1
2−2t2−2t=1+t2
3t2+2t−1=0
(3t−1)(t+1)=0
t=31 or t=−1
Case 1: tan2x=31
2x=arctan(31)+nπ
x=2arctan(31)+2nπ≈0.6435+2nπ
Case 2: tan2x=−1
2x=−4π+nπ
x=−2π+2nπ
Therefore, the general solutions are x≈0.6435+2nπ and x=−2π+2nπ, where n is an integer.