Answer:
Her linear velocity on the outer edge is 3 m/s
Her rotational velocity, is constant at 2 RPM
Step-by-step explanation:
The given parameters are;
The radius of the rotating platform = r
The linear velocity v(t) = 1 m/s
The position Emily is riding = 1/3 the distance from the center
The rotational velocity = 2 RPM = 2 Revolutions per minute
The formula for angular velocity, ω is given as follows;
ω = θ/t
Where;
θ = The angle rotated
t = The time taken for the rotation
Given that the rotational velocity = 2 RPM
1 revolution = 2·π radians
The angular velocity, ω = 2×π×(2 RPM) = 4·π rad/min = 4·π/60 rad/seconds
ω = 4·π/60 rad/seconds
The linear velocity, v = r₁×θ/t = r₁×ω
Where;
r₁ = 1/3 × r
v = 1 m/s = 1/3 × r × 4·π/60 rad/seconds
∴ r = 1/(1/3 × 4·π/60) = 45/π meters
r = 45/π meters
Therefore her linear velocity, v₂ and her rotational velocity if she moves to the outer edge will be given as follows;
v₂ = r × ω = 45/π × 4·π/60 = 3 m/s
Her linear velocity on the outer edge, v₂ = 3 m/s
Her rotational velocity, remains at 2 RPM.