Lecture 15

•Review:

•Energy storage and dynamic systems •Basic time-varying signals

•Capacitors •Related educational materials:

–Chapter 6.3

Dynamic Systems

• We now consider circuits containing energy storage

elements

• The circuits are dynamic systems • They are governed by differential equations • We need to be concerned with the input and output

of the system as functions of time

• The system output depends upon the state of the system

at previous times

Basic Time-Varying Signals

• Step functions

u

0

( t )

 0  1

, , t t

  0 0 • Exponential functions

f ( t )



Ae



t



, t



0 f(t) A 0.368A

0



t

Example: Sliding mass with friction

• • • Do forced, natural response; input and output response plots Time constant and effect of mass on time constant Notes: – Mention transient, steady-state – Natural vs. forced response – Homogeneous vs. particular solution

Energy storage elements – capacitors

• Capacitors store energy as an electric field • In general, constructed of two conductive elements

separated by a non-conductive material

• Circuit symbol: • C is the capacitance • Units are Farads (F)

Capacitors

• Voltage-charge relation:

q ( t )



Cv ( t )

• Recall:

i ( t )



dq ( t ) dt

• So:

i ( t )



d dt



Cv ( t )

 

C dv ( t ) dt

Capacitor voltage-current relations

• Differential form: • Integral form:

• Annotate previous slide to show initial voltage, define times on integral, sketchy derivation of integration of differential form to get integral form.

Important notes about capacitors 1. If voltage is constant, no current flows through the capacitor

• If nothing in the circuit is changing

with time, capacitors act as open circuits 2. Sudden changes in voltage require infinite current

• The voltage across a capacitor must

be a continuous function of time

• Power:

Capacitor Power and Energy

• Energy: 

t

1 2

Cv

2

( t )

 

Example

•

The voltage applied to the capacitor by the source is as shown. Plot the power absorbed by the capacitor and the energy stored in the capacitor as functions of time.

10 5 0 0 1 2 3 4 Time,

m

s

Example – continued

Example – continued

Series combinations of capacitors +

v 1 (t)

+

v 2 (t)

+

v N (t)

-

Series combinations of capacitors

• A series combination of capacitors can be

represented as a single equivalent capacitance

Þ

Parallel combinations of capacitors

i 1 (t) i 2 (t) i N (t)

Parallel combinations of capacitors

• A parallel combination of capacitors can be

represented as a single equivalent capacitance

Þ

Example

•

Determine the equivalent capacitance, C eq