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Logic Families

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Based on Underlying Semiconductor Technology. Transistor-Transistor Logic: TTL ... MOSFETs on input to provide high input impedance ... – PowerPoint PPT presentation

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Title: Logic Families


1
Logic Families
  • ECE-331, Digital Design
  • Dr. Ron Hayne
  • Electrical and Computer Engineering

2
Logic Implementation
  • Physical Phenomena With Two States Can Be Used to
    Implement Switching Algebra
  • Most Common
  • Voltage
  • 0V gt logic 0
  • Positive voltage gt logic 1
  • Current
  • flowing gt logic 1

3
Logic Families
  • Based on Underlying Semiconductor Technology
  • Transistor-Transistor Logic TTL
  • Bipolar junction transistors, BJT
  • Metal Oxide Semiconductors MOS
  • Field effect transistors, FET

4
MOS Logic Families
  • MOSFET
  • NMOS n-channel
  • Enhancement Mode
  • Depletion Mode
  • PMOS p-channel
  • Enhancement Mode
  • Depletion Mode

5
MOSFET
  • Four Terminal Device, 3 active
  • Source
  • Drain
  • Gate control terminal
  • Small change in source-gate voltage causes large
    change in resistivity between source and drain
  • Body non-active terminal
  • Typically connected to low (NMOS) or high (PMOS)
    voltage

6
MOSFET
  • (Almost) Linear Voltage Amplifier
  • Can Be Operated As a Switch to Implement and
    Change Logic Values
  • Low Power Consumption Since Operated by Voltage
    vice Current
  • Power dissipated in charging/discharging various
    device capacitances through unavoidable
    resistances

7
MOSFET Symbols
  • Enhancement NMOS
  • Multiple symbols
  • Positive VGS reduces resistivity from SD
  • Depletion NMOS
  • Multiple symbols

8
MOSFETs as Switches
9
Static NMOS
  • Totem-Pole Output
  • Does not need to be refreshed static
  • PMOS Acts as Constant Current Source for Active
    Pull-Up
  • Faster rise-times

10
Dynamic NMOS
  • Output 1 Unless Discharged
  • f1 Charges Output
  • f2 Conditionally Discharges Output

11
Static CMOS
  • Complementary MOS 2-input NAND

12
CMOS NAND Gate
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H
H L
H H
A B Q1 Q2 Q3 Q4 Z
L L
L H
H L
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off
L H
H L
H H
13
CMOS NAND Gate
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H
H L
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on
H L
H H
14
CMOS NAND Gate
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L off on on off H
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L off on on off
H H
15
CMOS NAND Gate
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L off on on off H
H H off off on on L
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L off on on off H
H H
A B Q1 Q2 Q3 Q4 Z
L L on on off off H
L H on off off on H
H L off on on off H
H H off off on on
16
Bipolar Logic Families
  • Bipolar Junction Transistor
  • Three Active Terminals
  • Collector
  • Base Control Terminal
  • Small change in Ibe causes large change in Ice
  • Emitter

17
Bipolar Junction Transistor
  • Nonlinear Current Amplifier
  • Can Be Operated As a Switch to Implement and
    Change Logic Values
  • Relatively High Power Consumption Since Operated
    by Current Flow vice Voltage
  • Power dissipated in bulk material due to (small)
    base current and (large) collector current

18
BJT Types
  • NPN
  • Positive current flowing from base to emitter
    controls current flowing from collector to
    emitter
  • PNP
  • Negative base current controls Ice

collector
base
emitter
19
TTL NAND Gate
20
TTL NAND Gate
H
L
L
21
TTL NAND Gate
on
H
L
off
on
off
H
22
TTL NAND Gate
on
H
H
off
on
off
L
23
TTL NAND Gate
L
H
H
24
Schottky TTL
  • High speed variant of TTL
  • Schottky transistors which have faster switching
    speed
  • Schottky-barrier diode connected from base to
    collector to prevent transistor from going into
    saturation

25
Merged Transistor Logic
  • Minimal TTL Implementation to Reduce Number of
    Passive, Power Dissipating Components
  • Integrated Injection Logic I2L
  • Multiple collector NPN bipolar transistors
  • Can be wire-ord to create all logic functions

26
Emitter-Coupled Logic
  • Current steering rather than saturating
    transistors to represent logic 0/1
  • Extremely high-speed

27
BiCMOS
  • MOSFETs on input to provide high input impedance
  • BJTs on output to provide high output current
    switching and good load driving capability

28
Noise Margin
  • Difference Between the Worst Case Output Voltage
    of One Stage and Worst Case Input Voltage of Next
    Stage
  • Greater the Difference, the More Unwanted Signal
    That Can Be Added Without Causing Incorrect Gate
    Operation

29
Noise Margin
  • NMhigh VOHmin - VIHmin
  • NMlow VILmax - VOLmax

Sample Data Sheet
30
Speed
  • Rise Time
  • Time from 10 to 90 of signal
  • Fall Time
  • Time from 90 to 10 of signal
  • Propagation Delay
  • Time from input signal reaching 50 point to
    output signal reaching 50 point

31
Propagation Delay
Sample Data Sheet
32
Power Dissipation
  • Static
  • I2R losses due to passive components
  • Dynamic
  • I2R losses due to charging and discharging
    capacitances through resistances

33
Fan-In
  • Number of input signals to a gate
  • Not an electrical property

34
Fan-Out
  • A Measure of the Ability of the Output of One
    Gate to Drive the Input of Subsequent Gates
  • Usually Specified As Standard Loads Within a
    Single Family
  • May Have to Compute Based on Current Drive
    Requirements When Mixing Families

35
Fan-Out
Sample Data Sheet
36
Wired-Logic
  • Open collector outputs connected together to a
    common pull-up resistor
  • Any collector can pull the signal line low
  • Logically an AND gate

37
Tri-State Logic
  • Both output transistors of totem-pole output are
    turned off
  • Usually used to bus multiple signals on the same
    wire
  • Gates not enabled present high-Z to bus and
    therefore do not interfere with other gates
    putting signals on the bus

38
End of Lecture
  • MOS
  • TTL
  • Schottky
  • ECL
  • Noise Margin
  • Speed
  • Power
  • Fan Out
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