Solveeit Logo
Login

Question

Question: Find the value of x, if sin x, sin 2x, sin 3x are in A.P A) \(n\pi ,{\text{ }}n \in l\) B) \(nx...

Find the value of x, if sin x, sin 2x, sin 3x are in A.P
A) nπ, nln\pi ,{\text{ }}n \in l
B) nx, nlnx,{\text{ }}n \in l
C) 2nπ, nl2n\pi ,{\text{ }}n \in l
D) (2n+1)π, nl\left( {2n + 1} \right)\pi ,{\text{ }}n \in l

Explanation

Solution

Hint: First use the property of arithmetic progression to the given terms and obtain an equation using trigonometric identities. Solve them using trigonometric equation solutions.

Complete step-by-step answer:

Given that sinx\sin x, sin2x\sin 2x, sin3x\sin 3x are in arithmetic progression.
We know that if a,b and c are in arithmetic progression, then the successive terms have equal difference, that is,
2b = a + c2{\text{b = a + c}}
Using the above relation in the given problem, we get
2sin2x=sinx+sin3x —- (1)2\sin 2x = \sin x + \sin 3x{\text{ ---- (1)}}
We know from trigonometric sum to product formula that
sinx+siny=2sin(x+y2)cos(xy2)\sin x + \sin y = 2\sin \left( {\dfrac{{x + y}}{2}} \right)\cos \left( {\dfrac{{x - y}}{2}} \right)
Using the above formula in the RHS of equation (1)(1), we get,
2sin2x=sin3x+sinx=2sin(3x+x2)cos(3xx2) 2sin2x=2sin(2x)cos(x)  2\sin 2x = \sin 3x + \sin x = 2\sin \left( {\dfrac{{3x + x}}{2}} \right)\cos \left( {\dfrac{{3x - x}}{2}} \right) \\\ \Rightarrow 2\sin 2x = 2\sin \left( {2x} \right)\cos \left( x \right) \\\
Rearranging the above obtained equation, we get
2sin(2x)(1cosx)=02\sin \left( {2x} \right)\left( {1 - \cos x} \right) = 0
sin(2x)=0 —- (2)\Rightarrow \sin \left( {2x} \right) = 0{\text{ ---- (2)}}
Or (1cosx)=0 —- (3)\left( {1 - \cos x} \right) = 0{\text{ ---- (3)}}
Now we need to solve equations (2)(2) and (3)(3) and then obtain the common solution.
We know that the general solution of sinz=0\sin z = 0 is z=nπ , nlz = n\pi {\text{ , }}n \in l ,where ll denotes integers.
Using above in equation (2)(2),we get,
sin(2x)=0 2x=nπ x=nπ2nl —- (4)  \sin \left( {2x} \right) = 0{\text{ }} \Rightarrow 2x = n\pi \\\ \Rightarrow x = \dfrac{{n\pi }}{2}{\text{, }}n \in l{\text{ ---- (4)}} \\\

Similarly, we know that the general solution of cosz=1\cos z = 1 is z=2nπ , nlz = 2n\pi {\text{ , }}n \in l,where ll denotes integers.
Using above in equation (3)(3),we get,
cos(x)=1 x=2nπ x=2nπ,nl —- (5)  \cos \left( x \right) = 1{\text{ }} \Rightarrow x = 2n\pi \\\ \Rightarrow x = 2n\pi ,n \in l{\text{ ---- (5)}} \\\
The intersection of solutions (4)(4)and (5)(5) is x=2nπnlx = 2n\pi {\text{, }}n \in l, which satisfies both the equations.
Hence (C). x=2nπnlx = 2n\pi {\text{, }}n \in l is the correct answer.

Note: Properties of arithmetic progression and solutions of the trigonometric equations should be kept in mind while solving problems like above. The intersection of solutions should always be verified with the original equations.