We have

Restoring torque = Force of gravity on disc and rod which is same in both cases.

$$\bullet$$ Case A : The moment of inertia is

$${I_A} = {{M{R^2}} \over 2} + M{L^2} + {{m{l^3}} \over 3}$$

Therefore,

$${\tau _A} = - {I_A}\omega _A^2\theta = - \left( {{{M{R^2}} \over 2} + M{L^2} + {{m{l^3}} \over 3}} \right)\omega _A^2\theta $$

$$\bullet$$ Case B : The moment of inertia is

$${I_B} = {{m{l^3}} \over 3} + M{L^2}$$

Therefore,

$${\tau _B} = - {I_B}\omega _B^2\theta = - \left( {{{m{l^3}} \over 3} + M{L^2}} \right)\omega _B^2\theta $$

since $${\tau _A} = {\tau _B} \Rightarrow {\omega _A} < {\omega _B}$$.