There is a series `LCR` curcuit (as shown). An alternating source of emf having voltage `V=V_(0) sin omega t` is applied between `M` & `N`.

Here `V_(M)-V_(N)=V_(0) sin omega t and 1/(omegaC)-omegaL=R`
R.M.S value of potential difference across capacitor will be

There is a series LCR curcuit (as shown). An alternating source of emf having voltage V=V_(0) sin omega t is applied between M & N . Here V_(M)-V_(N)=V_(0) sin omega t and 1/(omegaC)-omegaL=R Potential difference across inductor i.e. V_(Q)-V_(N) is

There is a series LCR curcuit (as shown). An alternating source of emf having voltage V=V_(0) sin omega t is applied between M & N . Here V_(M)-V_(N)=V_(0) sin omega t and 1/(omegaC)-omegaL=R The potential difference across R has got a phase difference of theta of alternating source of enf. where

The average value of an alternating voltage V=V_(0) sin omega t over a full cycle is

The r.m.s. value of potential difference V shown in the figure is :

A small signal voltage V(t)=V_(0)sin omegat is applied across an ideal capacitor C :

Give expression for average value of a.c. voltage V = V_(0) sin omega t over interval t = 0 to t = (pi)/(omega)

The voltage over a cycle varies as V=V_(0)sin omega t for 0 le t le (pi)/(omega) =-V_(0)sin omega t for (pi)/(omega)le t le (2pi)/(omega) The average value of the voltage one cycle is