Transient response of LCR circuits
==================================
.. image:: schematics/RLC-circuit.svg
   :width: 300px

Closing the switch in the cicuit shown above will change the voltage across the
capacitor. Depending on the relative values of L,C and R , the voltage may
show oscillations or it may change in an exponential manner.

**Objective**

Apply a step voltage to an LCR circuit. Capture and analyse the resulting
voltage across the capacitor.

**Procedure**

.. image:: schematics/RLCtransient.svg
   :width: 300px

-  Use the 3000 turn coil and :math:`0.1~\mu F` capacitor
-  Click on 5->0V STEP. Adjust x-axis and repeat if required.
-  FIT the graph to find the resonant frequency & Damping factor.
-  Repeat with increased capacitance and resistance values.


.. image:: pics/RLCtransient-screen.png
   :width: 500px

The values chosen are for an underdamped response. The coil has in inductance
more than 100mH and a resistance of around 500 :math:`\Omega`.
To increase damping, you may add a series resistor, or use a larger value
capacitor.

**Discussion**

Explore the oscillatory nature of L and C in series. Resonant frequency
of series LC circuit is given by :math:`f_0 = 1/(2\pi\sqrt{LC})`. The damping
factor is :math:`R/(2\sqrt{LC})`, and it is equal to 1 for critical
damping.  Depending upon the value of C/L and R, the response could be under-damped,
critically-damped or over-damped.

We have used the 3000 turn coil and a :math:`0,1~\mu F` capacitor. The voltage
across the capacitor after a 5 to 0V step is shown in figure. The
measured resonant frequency tallies with :math:`f = 1/(2\pi\sqrt{LC})`,
within the component tolerance values.

http://en.wikiversity.org/wiki/RLC\_circuit.
