Week 4b, Slide 1EECS42, Spring 2005Prof. White Notes 1.Midterm 1 – Thursday February 24 in...
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Transcript of Week 4b, Slide 1EECS42, Spring 2005Prof. White Notes 1.Midterm 1 – Thursday February 24 in...
Week 4b, Slide 1EECS42, Spring 2005 Prof. White
Notes
1. Midterm 1 – Thursday February 24 in class.Covers through text Sec. 4.3, topics of HW 4. GSIs will review material in discussion sections prior to the exam. No books at the exam, no cell phones, you may bring one 8-1/2 by 11 sheet of notes (bothsides of page OK), you may bring a calculator, and you don’t need a blue book.
Week 4b, Slide 2EECS42, Spring 2005 Prof. White
Lecture Week 4b
OUTLINE– Transient response of 1st-order circuits– Application: modeling of digital logic
gate
ReadingChapter 4 through Section 4.3
Week 4b, Slide 3EECS42, Spring 2005 Prof. White
Transient Response of 1st-Order Circuits• In Lecture Week 4a, we saw that the currents and
voltages in RL and RC circuits decay exponentially with time, with a characteristic time constant , when an applied current or voltage is suddenly removed.
• In general, when an applied current or voltage suddenly changes, the voltages and currents in an RL or RC circuit will change exponentially with time, from their initial values to their final values, with the characteristic time constant :
where x(t) is the circuit variable (voltage or current)
/)(0
0 )()( tt
ff extxxtx
xf is the final value of the circuit variable
t0 is the time at which the change occurs
Week 4b, Slide 4EECS42, Spring 2005 Prof. White
Procedure for Finding Transient Response
1. Identify the variable of interest• For RL circuits, it is usually the inductor current iL(t)
• For RC circuits, it is usually the capacitor voltage vc(t)
2. Determine the initial value (at t = t0+) of the
variable • Recall that iL(t) and vc(t) are continuous variables:
iL(t0+) = iL(t0
) and vc(t0+) = vc(t0
)
• Assuming that the circuit reached steady state before t0 , use the fact that an inductor behaves like a short circuit in steady state or that a capacitor behaves like an open circuit in steady state
Week 4b, Slide 5EECS42, Spring 2005 Prof. White
Procedure (cont’d)
3. Calculate the final value of the variable (its value as t ∞)
• Again, make use of the fact that an inductor behaves like a short circuit in steady state (t ∞) or that a capacitor behaves like an open circuit in steady state (t ∞)
4. Calculate the time constant for the circuit = L/R for an RL circuit, where R is the Thévenin
equivalent resistance “seen” by the inductor = RC for an RC circuit where R is the Thévenin
equivalent resistance “seen” by the capacitor
Week 4b, Slide 6EECS42, Spring 2005 Prof. White
Example: RL Transient AnalysisFind the current i(t) and the voltage v(t):
t = 0
i +
v
–
R = 50
Vs = 100 V + L = 0.1 H
1. First consider the inductor current i2. Before switch is closed, i = 0
--> immediately after switch is closed, i = 03. A long time after the switch is closed, i = Vs / R = 2 A
4. Time constant L/R = (0.1 H)/(50 ) = 0.002 seconds Amperes 22 202)( 500002.0/)0( tt eeti
Week 4b, Slide 7EECS42, Spring 2005 Prof. White
t = 0
i +
v
–
R = 50
Vs = 100 V + L = 0.1 H
Now solve for v(t), for t > 0:
From KVL, 5022100100)( 500teiRtv
= 100e-500t volts`
Week 4b, Slide 8EECS42, Spring 2005 Prof. White
Example: RC Transient AnalysisFind the current i(t) and the voltage v(t):
t = 0i +
v
–R2 = 10 kVs = 5 V +
C = 1 F
1. First consider the capacitor voltage v2. Before switch is moved, v = 0
--> immediately after switch is moved, v = 03. A long time after the switch is moved, v = Vs = 5 V
4. Time constant R1C = (104 )(10-6 F) = 0.01 seconds Volts 55 505)( 10001.0/)0( tt eetv
R1 = 10 k
Week 4b, Slide 9EECS42, Spring 2005 Prof. White
t = 0i +
v
–R2 = 10 kVs = 5 V +
C = 1 F
4
100
1 10555)()(
ts e
RtvVti
R1 = 10 k
Now solve for i(t), for t > 0:
From Ohm’s Law, A
= 5 x 10-4e-100t A
Week 4b, Slide 10EECS42, Spring 2005 Prof. White
Week 4b, Slide 11EECS42, Spring 2005 Prof. White
Week 4b, Slide 12EECS42, Spring 2005 Prof. White
When we perform a sequence of computations using a digital circuit, we switch the input voltages between logic 0 (e.g., 0 Volts) and logic 1 (e.g., 5 Volts).
The output of the digital circuit changes between logic 0 and logic 1 as computations are performed.
Application to Digital Integrated Circuits (ICs)
Week 4b, Slide 13EECS42, Spring 2005 Prof. White
• Every node in a real circuit has capacitance; it’s the charging of these capacitances that limits circuit performance (speed)
We compute with pulses.
We send beautiful pulses in:
But we receive lousy-looking pulses at the output:
Capacitor charging effects are responsible!
time
volta
ge
time
volta
ge
Digital Signals
Week 4b, Slide 14EECS42, Spring 2005 Prof. White
Circuit Model for a Logic Gate• Recall (from Lecture 1) that electronic building blocks
referred to as “logic gates” are used to implement logical functions (NAND, NOR, NOT) in digital ICs– Any logical function can be implemented using these gates.
• A logic gate can be modeled as a simple RC circuit:
+
Vout
–
R
Vin(t) + C
switches between “low” (logic 0) and “high” (logic 1) voltage states
Week 4b, Slide 15EECS42, Spring 2005 Prof. White
Transition from “0” to “1”(capacitor charging)
time
Vout
0
Vhigh
RC
0.63Vhigh
Vout
Vhigh
timeRC
0.37Vhigh
Transition from “1” to “0”(capacitor discharging)
(Vhigh is the logic 1 voltage level)
Logic Level Transitions
RCthighout eVtV /1)( RCt
highout eVtV /)(
0
Week 4b, Slide 16EECS42, Spring 2005 Prof. White
What if we step up the input,
wait for the output to respond,
then bring the input back down?
time
Vin
0
0
time
Vin
0
0
Vout
time
Vin
0
0
Vout
Sequential Switching
Week 4b, Slide 17EECS42, Spring 2005 Prof. White
The input voltage pulse width must be large enough; otherwise the output pulse is distorted.(We need to wait for the output to reach a recognizable logic level, before changing the input again.)
0123456
0 1 2 3 4 5Time
Vout
Pulse width = 0.1RC
0123456
0 1 2 3 4 5Time
Vout
0123456
0 5 10 15 20 25Time
Vout
Pulse Distortion
+
Vout
–
R
Vin(t) C+
–
Pulse width = 10RCPulse width = RC
Week 4b, Slide 18EECS42, Spring 2005 Prof. White
Vin
RVout
C
Suppose a voltage pulse of width5 s and height 4 V is applied to theinput of this circuit beginning at t = 0:
R = 2.5 kΩC = 1 nF
• First, Vout will increase exponentially toward 4 V.
• When Vin goes back down, Vout will decrease exponentially back down to 0 V.
What is the peak value of Vout?
The output increases for 5 s, or 2 time constants. It reaches 1-e-2 or 86% of the final value.
0.86 x 4 V = 3.44 V is the peak value
Example
= RC = 2.5 s
Week 4b, Slide 19EECS42, Spring 2005 Prof. White
00.5
11.5
22.5
33.5
4
0 2 4 6 8 10
Vout(t) =4-4e-t/2.5s for 0 ≤ t ≤ 5 s
3.44e-(t-5s)/2.5s for t > 5 s{t (s)
Vout(t)
Week 4b, Slide 20EECS42, Spring 2005 Prof. White