Derive an experssion for the average power in LCR circuit connected to a.c. supply. Hence define power factor. Show that average power cousumed per cy

Power in `LCR` circuit /`AC` circuit: the voltage `V=V_(m) sin omegat` is applied to a series `RLC` circuit.Then the current in the circuit is given by `I=I_(m)sin (omegat+phi)`
where `I_(m)=V_(m)/Z` and `phi=tan^(-1)((X_(L)-X_(C))/R)`
The instaneous power `P` supplied to the source is:
`P=VI`
`P=V_(m)sin omegat.I_(m)sin(omegat+phi)`
`=(V_(m)I_(m))/2 . 2sin omegat sin(omegat+phi)`
`=(V_(m)I_(m))/2 [cos(omegat-omegat-phi)]-cos(omegat+omegat+phi)`
`[because 2 sin A sin B=cos (A-B)-cos (A+B)]`
`=(V_(m)I_(m))/2[cos phi-cos (2omegat+phi)]`...(i)
`because` The average power over a cycle is given by the average of the two terms in `RHS` of equation (i).The second terms in `RHS` is time dependent.Its average is zero
[`because` Positive half of the cosine cancles the negative half]
Therefore, average power
`barP=(V_(m)I_(m))/2cos phi=V_(m)/sqrt2I_(m)/sqrt2cosphi`
`barP=V_(rms)I_(rms)cos phi`
Where `cosphi` is called power factor.It depends on voltage, current and phase angle `phi` CaseI:For resistive circuit:If circuit contains only resistance `R`
`therefore phi=0`, Therefore
`P=V_(rms)I_(rms)cos 0=V_(rms)I_(rms)`
Therefore, power disispation is maximum
Case II: For pure inductive or capacitive circuit, the phase difference between voltage and current is `pi/2`
`thereforephi=pi/2 rArrcos phi="cos" pi/2=0`
`therefore barP=V_(rms)I_(rms)cos phi=0`
Therefore, power dissipation is zero. hence, no power is dissipated even through a current is flowing in the circuit, the current is called wattless current.