Given:

(a) Moment of Inertia of the man-platform system = 7.6 Kgm²

Moment of inertia when the man stretches his hands to a distance of 90 cm.

We know, I = 2 × mr²

Where,

m = mass

r = distance of mass from axis of rotation

Using the above formula, we get,

⇒ I = 2 × 5Kg × (0.9m)²

⇒ I = 8.1 Kgm²

Now, the Initial moment of inertia of the system,

I_i = 7.6 + 8.1 = 15.7 Kgm²

Angular speed, ω_i = 30 rev/min

Angular momentum, L_i = I_iω_i

L_i = 15.7Kgm² × 30rev/min

⇒ L_i = 471 Kgm²/sec …(i)

Moment of inertia when the man folds his hands to a distance of 20 cm,

I = 2 × mr²

Where,

m = mass

r = distance of mass from axis of rotation

⇒ I = 2 × 5Kg × (0.2m)²

⇒ I = 0.4 Kgm²

Final moment of inertia, I_f = 7.6 + 0.4 = 8 Kgm²

Final angular speed = ω_f

Final angular momentum = L_f = I_fω_f

L_f = 0.79 ω_f …(ii)

From the conservation of angular momentum, We have

I_iω_i = I_fω_f

From equation (i) and (ii),

ω_f = 15.7 Kg m² × ((30rev/sec)/8 Kgm²)

ω_f = 58.88 rev/min

(b) Kinetic energy is not conserved in the given process. In fact, with the decrease in moment of inertia, kinetic energy increases. The additional kinetic energy comes from the work done by the man to fold his hands towards himself.