The correct option is
C 2R1R2R1+R2When the projectile is from top to 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−12gcosθ T2 (Using second equation of motion along Y-axis)
⇒T=2vsin(α−θ)gcosθ(1) If the projected object 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=R1=v2gcos2θ[sin(2α−θ)−sinθ] Clearly, the range
R1(=OA) will be maximum when
sin(2α−θ) is maximum, i.e., 1.
This would mean
2α−θ=π2 or α=θ2+π4 Maximum range on the inclined plane from bottom to top can be denoted by
R1.
∴R1=v2gcos2θ(1−sinθ)=v2(1−sinθ)g(1−sin2θ)=v2(1−sinθ)g(1+sinθ)(1−sinθ)=v2g(1+sinθ) When the projectile is from top to bottom of the inclined plane.
Range of a projectile when it is from bottom of 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=R2=v2g(1−sin2θ)[1+sinθ]R2=v2g(1−sinθ) We know that the maximum range of a projectile from the bottom and top of an inclined plane are, respectively
R1=v2g(1+sinθ) and
R2=v2g(1−sinθ) Then,
1R1+1R2=g(1+sinθ)v2+g(1−sinθ)v2 ⇒R1+R2R1R2=2gv2⇒2R1R2R1+R2=v2g Maximum range of a projectile on a horizontal surface
Rmax=v2g Thus,
Rmax=2R1R2R1+R2