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Transient Excitation of First-Order Circuits

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Title: Transient Excitation of First-Order Circuits

1
Transient Excitation of First-Order Circuits

What is transient excitation and why is it
important?
What is a first-order circuit?
What are natural response and step response?
Transients in RL circuits (briefly)
Transients in RC circuits ? application to
computer circuits

2
Types of Circuit Excitation
Steady-State Excitation
OR
(DC Steady-State)
Sinusoidal (Single- Frequency) Excitation ?AC
Steady-State
Transient Excitation
3
First-Order Circuits

A circuit that contains only sources, resistors
and an inductor is called an RL circuit.
A circuit that contains only sources, resistors
and a capacitor is called an RC circuit.
RL and RC circuits are called first-order
circuits because their voltages and currents are
described by first-order differential equations.

R
R
i
i

vs

vs
L
C
4
Review (Conceptual)

Any first-order circuit can be reduced to a
Thévenin (or Norton) equivalent connected to
either a single equivalent inductor or capacitor.
In steady state, an inductor behaves like a short
circuit
In steady state, a capacitor behaves like an open
circuit

RTh

VTh
C
L
RN
IN
5

The natural response of an RL or RC circuit is
its behavior (i.e., current and voltage) when
stored energy in the inductor or capacitor is
released to the resistive part of the network
(containing no independent sources).
The step response of an RL or RC circuit is its
behavior when a voltage or current source step is
applied to the circuit, or immediately after a
switch state is changed.

6
Natural Response of an RL Circuit

Consider the following circuit, for which the
switch is closed for t lt 0, and then opened at t
0
Notation
0 is used to denote the time just prior to
switching
0 is used to denote the time immediately after
switching
The current flowing in the inductor at t 0 is
Io

t 0
i
v
L
Ro
R
Io
7
Solving for the Current (t ? 0)

For t gt 0, the circuit reduces to
Applying KVL to the LR circuit yields first-order
D.E.
Solution

i
v
L
Ro
R
Io
I0e-(R/L)t
8
Solving for the Voltage (t gt 0)
v
L
Ro
R
Io

Note that the voltage changes abruptly (step
response)

-

v
0
)
0
(
-

gt
)
/
(
t
L
R
Re
I
iR
t
v
t
)
(

0,
for
o

Þ
I0R
v
)
0
(

9
Time Constant t

In the example, we found that
Define the time constant
At t t, the current has reduced to 1/e (0.37)
of its initial value.
At t 5t, the current has reduced to less than
1 of its initial value.

(sec)
10
Transient response of RC circuits and application
to computer circuits driven by binary voltage
pulses
11
Capacitors and Stored Charge

So far, we have assumed that electrons keep on
moving around and around a circuit.
Current doesnt really flow through a
capacitor. No electrons can go through the
insulator.
But, we say that current flows through a
capacitor. What we mean is that positive charge
collects on one plate and leaves the other.
A capacitor stores charge. Theoretically, if we
did a KCL surface around one plate, KCL could
fail. But we dont do that.
When a capacitor stores charge, it has nonzero
voltage. In this case, we say the capacitor is
charged. A capacitor with zero voltage has no
charge differential, and we say it is
discharged.

12
Capacitors in circuits

If you have a circuit with capacitors, you can
use KVL and KCL, nodal analysis, etc.
The voltage across the capacitor is related to
the current through it by a differential equation
instead of Ohms law.

13
CAPACITORS
(
C
i(t)
capacitance is defined by
14
Charging a Capacitor with a constant current
V(t)

?
(
C
i
voltage
time
15
Discharging a Capacitor through a resistor

?
V(t)
i
R
C
i
This is an elementary differential equation,
whose solution is the exponential
Since
16
Voltage vs time for an RC discharge
Voltage
Time
17
Natural Response of an RC Circuit

Consider the following circuit, for which the
switch is closed for t lt 0, and then opened at t
0
Notation
0 is used to denote the time just prior to
switching
0 is used to denote the time immediately after
switching
The voltage on the capacitor at t 0 is Vo

t 0
Ro
v
?
R
Vo
C
18
Solving for the Voltage (t ? 0)

For t gt 0, the circuit reduces to
Applying KCL to the RC circuit
Solution

i
v
Ro
?
C
R
Vo
19
Solving for the Current (t gt 0)
i
v
Ro
?
C
R
Vo

Note that the current changes abruptly

20
Time Constant t

In the example, we found that
Define the time constant
At t t, the voltage has reduced to 1/e (0.37)
of its initial value.
At t 5t, the voltage has reduced to less than
1 of its initial value.

(sec)
21
RC Circuit Model for a Digital Logic Circuit

The capacitor is used to model the response of a
digital circuit to a new voltage input
The digital circuit is modeled by
a resistor in series with a capacitor.
The capacitor cannot
change its voltage instantly,
as charges cant jump instantly
to the other plate, they must go through the
circuit!

R
Vout

Vin
Vout
C
_
_
22
RC Circuits Abound in Computers
We compute with pulses We send beautiful pulses
in
But we receive lousy-looking pulses at the output
Capacitor charging effects are responsible!

Every node in a circuit has natural capacitance,
and it is the charging of these capacitances that
limits real circuit performance (speed)

23
RC Circuit Model

Every digital circuit has natural resistance and
capacitance. In real life, the resistance and
capacitance can be estimated using
characteristics of the materials used and the
layout of the physical device.
The value of R and C
for a digital circuit
determine how long it will
take the capacitor to change its
voltagethe gate delay.

R
Vout

Vin
Vout
C
_
_
24
RC Circuit Model
R

With the digital context in mind, Vin will
usually be a time-varying voltage that switches
instantaneously between logic 1 voltage and logic
0 voltage.
We often represent this switching voltage with a
switch in the circuit diagram.

Vout

Vin
Vout
C
_
_
t 0
i
Vout
?
Vs 5 V
25
Analysis of RC Circuit
R
Vout

By KVL,
Using the capacitor I-V relationship,
We have a first-order linear differential
equation for the output voltage

Vin
Vout
I
C
_
_
26
Analysis of RC Circuit
R
Vout

What does that mean?
One could solve the
differential equation to get

Vin
Vout
I
C
_
_
27
Insight

Vout(t) starts at Vout(0) and goes to Vin
asymptotically.
The difference between the two values decays
exponentially.
The rate of convergence depends on RC. The
bigger RC is, the slower the convergence.

Vout
Vout
Vout(0)
Vin
bigger RC
Vout(0)
Vin
0
0
time
time
0
0
28
(No Transcript)
29
Time Constant

The value RC is called the time constant.
After 1 time constant has passed (t RC), the
above works out to
So after 1 time constant, Vout(t) has completed
63 of its transition, with 37 left to go.
After 2 time constants, only 0.372 left to go.

30
Transient vs.Steady-State
R
Vout

Vin
Vout
I
C
_
_

When Vin does not match up with Vout , due to an
abrupt change in Vin for example, Vout will begin
its transient period where it exponentially
decays to the value of Vin.
After a while, Vout will be close to Vin and be
nearly constant. We call this steady-state.
In steady state, the current through the
capacitor is (approx) zero. The capacitor
behaves like an open circuit in steady-state.
Why? I C dVout/dt, and Vout is constant in
steady-state.

31
General RC Solution

Every current or voltage (except the source
voltage) in an RC circuit has the following form
x represents any current or voltage
t0 is the time when the source voltage switches
xf is the final (asymptotic) value of the
current or voltage
All we need to do is find these values and plug
in to solve for any current or voltage in an RC
circuit.

32
Solving the RC Circuit

We need the following three ingredients to fill
in our equation for any current or voltage
x(t0) This is the current or voltage of
interest just after the voltage source switches.
It is the starting point of our transition, the
initial value.
xf This is the value that the current or
voltage approaches as t goes to infinity. It is
called the final value.
RC This is the time constant. It determines
how fast the current or voltage transitions
between initial and final value.

33
Finding the Initial Condition

To find x(t0), the current or voltage just after
the switch, we use the following essential fact
Capacitor voltage is continuous it cannot jump
when a switch occurs.
So we can find the capacitor voltage VC(t0) by
finding VC(t0-), the voltage before switching.
We can assume the capacitor was in steady-state
before switching. The capacitor acts like an
open circuit in this case, and its not too hard
to find the voltage over this open circuit.
We can then find x(t0) using VC(t0) using KVL
or the capacitor I-V relationship. These laws
hold for every instant in time.

34
Finding the Final Value

To find xf , the asymptotic final value, we
assume that the circuit will be in steady-state
as t goes to infinity.
So we assume that the capacitor is acting like an
open circuit. We then find the value of current
or voltage we are looking for using this
open-circuit assumption.
Here, we use the circuit after switching along
with the open-circuit assumption.
When we found the initial value, we applied the
open-circuit assumption to the circuit before
switching, and found the capacitor voltage which
would be preserved through the switch.

35
Finding the Time Constant

It seems easy to find the time constant it
equals RC.
But what if there is more than one resistor or
capacitor?
R is the Thevenin equivalent resistance with
respect to the capacitor terminals.
Remove the capacitor and find RTH. It might help
to turn off the voltage source. Use the circuit
after switching.

36
Natural Response Summary