A ring of thin wire with active resistance `R` and inductance `L` rotates with constant angular velocity `omega` in the external uniform magneitce field perpendicular to the rotation axis. In the process , the flux of magnetic induction of external field across the ring varies with time as `Phi=Phi_(0)cos omega t`. Demonstrate that (a) the inductive current in the ring varies with time as `I=I_(m) sin ( omegat-varphi)`, where `I_(m)=._(m) Phi//sqrt(R^(2)+ omega^(2)L^(2))` with `tan varphi=omegaL//R`, (b) the mean mechanical is defined by the formula `P=1//2 omega^(2) Phi_(0)^(2)R//(R^(2)+omega^(2)L^(2))`.

A ring of thin wire with active resistance `R` and inductance `L` rota

1.	A ring of thin wire with active resistance `R` and inductance `L` rotates with constant angular velocity `omega` in the external uniform magneitce field perpendicular to the rotation axis. In the process , the flux of magnetic induction of external field across the ring varies with time as `Phi=Phi_(0)cos omega t`. Demonstrate that (a) the inductive current in the ring varies with time as `I=I_(m) sin ( omegat-varphi)`, where `I_(m)=._(m) Phi//sqrt(R^(2)+ omega^(2)L^(2))` with `tan varphi=omegaL//R`, (b) the mean mechanical is defined by the formula `P=1//2 omega^(2) Phi_(0)^(2)R//(R^(2)+omega^(2)L^(2))`.
Answer» `(a)` We have `epsilon=-(dPhi)/( dt)=omegaPhi_(0)sin omegat=Ldot(I)+RI` Put `I=I_(m) sin ( omegat-varphi)`. Then `omegaPhi_(0)sin omegat =omegaPhi_(0){sin ( omega t-varphi)cos varphi+cos (o omega-varphi)sin varphi}` `=LI_(m) omegacos ( omegat-varphi)+RI_(m) sin (omegat-varphi)` so `RI_(M) = omega Phi_(0) cos varphi` and `LI_(m) = Phi _(0) sin varphi` or ` I_(m)=( omega Phi_(0))/( sqrt(R^(2)+omega^(2)L^(2)))` and `tan varphi=( omegaL)/( R)` `(b)` Mean mechanical power required to maintain rotation `=` energy loss per unit time `=(1)/(T)int_(0)^(T)RI^(2)dt=(1)/(2) RI_(m)^(2)=(1)/(2)(omega^(2) Phi_(0)^(2)R)/( R^(2)+omega^(2)L^(2))`

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