168 GEOMETRY AND TRIGONOMETRY
solutions (as shown in Chapter 15). Fig. 16.2 shows
a summary for angles of any magnitude.
Figure 16.2
Equations of the typeasin^2 A+bsinA+c= 0
(i) Whena= 0 ,bsinA+c=0, hence
sinA=−c
bandA=sin−^1(
−c
b)There are two values of Abetween 0◦ and
360 ◦which satisfy such an equation, provided
− 1 ≤c
b≤1 (see Problems 6 to 8).(ii)Whenb= 0 ,asin^2 A+c=0, hencesin^2 A=−c
a, sinA=√(
−c
a)andA=sin−^1√(
−c
a)If eitheraorcis a negative number, then
the value within the square root sign is posi-
tive. Since when a square root is taken there is
a positive and negative answer there are four
values ofAbetween 0◦and 360◦which sat-
isfy such an equation, provided− 1 ≤c
a≤ 1
(see Problems 9 and 10).(iii)Whena,bandcare all non-zero:
asin^2 A+bsinA+c=0 is a quadratic equa-
tion in which the unknown is sinA. The solution
of a quadratic equation is obtained either by fac-
torising (if possible) or by using the quadratic
formula:
sinA=−b±√
(b^2 − 4 ac)
2 a
(see Problems 11 and 12).(iv) Often the trigonometric identities
cos^2 A+sin^2 A=1, 1+tan^2 A=sec^2 A and
cot^2 A+ 1 =cosec^2 Aneed to be used to reduce
equations to one of the above forms (see
Problems 13 to 15).16.4 Worked problems (i) on
trigonometric equationsProblem 6. Solve the trigonometric equation
5 sinθ+ 3 =0 for values ofθfrom 0◦to 360◦.5 sinθ+ 3 =0, from which sinθ=−^35 =− 0. 6000Henceθ=sin−^1 (− 0 .6000). Sine is negative in the
third and fourth quadrants (see Fig. 16.3). The
acute angle sin−^1 (0.6000)= 36 ◦ 52 ′(shown asαin
Fig. 16.3(b)). Hence,θ= 180 ◦+ 36 ◦ 52 ′,i.e. 216 ◦ 52 ′ orθ= 360 ◦− 36 ◦ 52 ′,i.e. 323 ◦ 8 ′Figure 16.3