A plane surface is inclined making an angle θ with the horizontal. From the top of this inclined plane, a bullet is fired with velocity v. The maximum possible range of the bullet on the inclined plane is
A
v2g
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B
v2g(1+sinθ)
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C
v2g(1−sinθ)
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D
v2g(1+cosθ)
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Solution
The correct option is Cv2g(1−sinθ) When the bullet is fired from the bottom of the inclined plane. Resolving the motion parallel and perpendicular to the inclined plane as shown in the diagram, vx=vcos(α−θ)vy=vsin(α−θ)ax=−gsinθay=−gcosθ If T is the time of flight, then 0=vsin(α−θ)T−12gcosθT2 (Using second equation of motion along Y-axis) ⇒T=2vsin(α−θ)gcosθ(1) If the bullet covers horizontal distance OB in time T, OB=vcosα×T
Now, cosθ=OBOA (From the figure) ⇒OA=OBcosθ=vcosα×Tcosθ Using (1), ⇒OA=v2gcos2θ[2sin(α−θ)cosα] Using the identity 2sinAcosB=sin(A+B)+sin(A−B)
OA=v2gcos2θ[sin(2α−θ)−sinθ] Range of a projectile on an inclined plane was found to be OA=v2gcos2θ[sin(2α−θ)−sinθ]
Here α is the angle made by the direction of projection with the horizontal when it is projected from the bottom of the plane. When it is projected from the top of the plane, the angle made by the projectile with the inclined plane is α+θ.
That is θ is replaced with −θ in the above formula. Hence, OA=v2gcos2θ[sin(2a−(−θ))−sin(−θ)]=v2gcos2θ[sin(2α+θ)+sinθ]
OA is maximum when 2α+θ=π2 and sin(2α+θ)=1 ⇒OAmax=v2gcos2θ[1+sinθ]⇒OAmax=Rmax=v2g(1−sin2θ)[1+sinθ]=v2g(1−sinθ)