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LECTURE 2 DIGITAL ELECTRONICS

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Title: LECTURE 2 DIGITAL ELECTRONICS


1
LECTURE 2 DIGITAL ELECTRONICS
Dr Richard ReillyDept. of Electronic
Electrical EngineeringRoom 153, Engineering
Building
2
Digital Logic Families
  • Gates perform one or more operations.
  • simply electronic circuits composed of resistors,
    diodes and transistors
  • Originally gates were composed just from
    resistors and diodes, due to expense of
    transistors.
  • Due to fabrication procedures, all gates are now
    constructed exclusively from transistors.
  • The style in which transistors are connected
    characterises each logic family or library and
    gives it its unique name.

3
DIGITAL LOGIC FAMILIES
  •     Diode-Resistor Logic (DRL)
  •     Diode-Transistor Logic (DTL)
  •     Resistor-Transistor Logic (RTL)
  •  
  •     Transistor-Transistor (TTL)
  •     standard TTL
  •     Schottky-Clamped TTL
  •     Low-Power Schottky-Clamped TTL
  •     Advanced Schottky-Clamped TTL
  •  
  •     Emitter-Coupled Logic (ECL)
  •     ECL 10K Series
  •     ECL 100K Series

4
DIGITAL LOGIC FAMILIES
  •     Integrated Injection Logic (I2L)
  •     standard I2L
  •     Schottky I2L
  •     Schottky Transistor I2L
  •  
  •     NMOS
  •  
  •     CMOS Logic
  •     standard CMOS
  •     4000 Series CMOS Logic Family
  •     4000B and 74C Series
  •     74HC/HCT Series
  •     74AC/ACT Series
  •     BiCMOS

5
Metrics for Logic Gate Comparison
  • How do you compare these different logic families
    ?
  • Comparison on the application ?
  • Comparison on the cost ?
  • Any other ?

6
Metrics for Logic Gate Comparison
  • Before a discussion of the basic logic families,
    several metrics must be defined to allow
    comparison of different families.

7
Metrics for Comparing Logic Families
  • Logic Level
  • Noise Margin
  • Fan out
  • Power Dissipation
  • Propagation Delay

8
METRIC 1 Logic Levels
  • Circuit behaviour explained very well in terms of
    voltage levels measured in volts (V)
  • but not necessarily in terms of Boolean values 0
    and 1.
  •  
  • To accommodate these Boolean values, gate
    circuits are designed in such a way that only two
    voltage levels, high (H) and low (L) are
    observable in steady state at gate inputs and
    outputs.
  •  
  • Thus a mapping exists from 0 and 1 to voltage
    levels H and L.
  • Mapping can be accomplished in two different ways
  • Results in two different logic systems
  • positive and negative.

9
Logic Levels
  • Example
  • The gate circuit whose output is L only when both
    inputs are H
  • Performs the NAND operation in positive logic
  • Performs the NOR operation in negative logic
  •  
  • Similarly gate circuit whose output is L only
    whenever one input is H
  • Performs the NOR operation in positive logic
  • Performs the NAND operation in negative logic

10
New Symbol
  • To distinguish between positive and negative
    logic
  • a small triangle as a polarity indicator for
    negative logic in any input and output signal
    line.
  • Negative logic NAND (positive logic NOR)
  • The mixing of logic levels was practised
    frequently in the past when designers mixed gates
    from different logic families on the same board.
  • Since the mid-eighties or so, all new ICs have
    been made with the CMOS logic family, which uses
    positive logic.
  • Negative logic has fallen out of fashion.

11
Noise Margin
12
METRIC 2 Noise Margins
  • Gate circuits are constructed to sustain
    variations in input and output voltage levels.
  • variations are usually result of several
    different factors.
  •  
  • Batteries lose their full potential, causing the
    supply voltage to drop
  • High operating temperatures may cause a drift in
    transistor voltage and current characteristics
  • Spurious pulses may be introduced on signal lines
    by normal surges of current in neighbouring
    supply lines.

13
Noise Margins
  • All these undesirable voltage variations that are
    superimposed on normal operating voltage levels
    are called noise.
  •  
  • All gates designed to tolerate a certain amount
    of noise on their input and output ports.
  • The maximum noise voltage level that is tolerated
    by a gate is called a noise margin.
  •  
  •  
  • Noise margin derived from I/PO/P voltage
    characteristic
  • Measured under different operating conditions
  • Normally supplied in documentation about gate
    from manufacturer.

14
Noise Margins
  • Typical input/output voltage characteristic for
    (TTL) family
  • the output voltage is plotted as a function of
    the input voltage.

15
Noise Margins
  • The input/output voltage characteristic drifts
    under different operating conditions also show
    the drifting range by the shaded area.
  •  
  •  
  • From the figure we can see that the given gate
    operates in 3 different modes
  • High output
  • Transition
  • Low output

16
Noise Margins
  • High Mode
  • When VI is between 0 and 0.8 V
  • the output voltage VO is greater than 2.4 V
  • and
  • less than the supply voltage VCC, which is
    usually 5.0 V.
  • i.e 2.4V lt VO lt 5.0V
  •  
  • Transition Mode
  • When VI is between 0.8 and 2.0 V
  •     the gates switches from H to L

17
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18
Noise Margins
  • Low Mode
  • When VI is greater than 2.0 V
  •     the output voltage VO is greater than 0 V
  • and
  •     less than 0.4 V.
  • i.e 0V lt VO lt 0.4V

19
How to determine noise margins?
  • Compare input and output voltage ranges of gates
    in same family.
  •  
  • output voltage range of a driving gate on LHS
    input voltage range of the driven gate on RHS
  •  Any voltage between VOH and VCC is considered H.
  • any voltage between 0 and VOL is considered L.

20
How to determine noise margins?
  • Similarly
  • Any voltage between VIH and VCC is considered H
  • Any voltage between 0 and VIL is considered L
  • The voltage difference VOH - VIH called
    high-level noise margin
  • Any noise voltage smaller than VOH - VIH will be
    tolerated and will not change the output value of
    the driven gate.
  • For the same reason, the voltage difference VIL -
    VOL is called the low-level noise margin.

21
How to determine noise margins?
  • In the example of transistor-transistor logic
    (TTL)
  • VOH 2.4 V
  • VIH 2.0 V
  • VIL 0.8 V
  • VOL 0.4 V
  •  
  • Thus both high and low level noise margins are
    0.4 V.
  • Thus any noise smaller than 0.4 V will not
    disturb gate operation.
  • Such high noise margins, which are not available
    in analog circuits, make digital designs superior
    to analog.

22
Fan-Out
23
METRIC 3 Fan-out
  • To date have understood that each gate can drive
    several other gates.
  •  
  • The number of gates that each gate can drive,
    while providing voltage levels in the guaranteed
    range is called the standard load or fan-out.
  •  
  • The fan-out really depends on the amount of
    electric current a gate can source or sink while
    driving other gates.

24
Fan-out
  • When the gate output is H
  • Gate behaves as a current source since IOH flows
    out of the driver gate and into the set of driven
    gates.
  • The current IOH equals the sum of all input
    currents indicated by IIH, flowing into the
    driven gates.

25
Fan-out
  • When the gate output is L
  • Gate behaves as a current sink since IOL flows
    into the gate and out of the driven gates.
  • The current IOL is again equal to the sum of all
    input currents IIL, flowing out of all the driven
    gates.

26
Fan-out
  • Since all gates in a logic family are constructed
    in such a way that each gate requires the same
    IIH and the same IIL,
  • can compute fan-out in the following way

27
Fan-out
  • Example
  • Input and output current for the
    transistor-transistor logic (TTL) family are the
    following
  •  
  • IOH 400 ?A
  • IOL 16 ?A
  • IIH 40 ?A
  • IIL 1.6 ?A
  •  
  • Therefore the fan-out is ?

28
Fan-out
  • This means that each gate can drive 10 other
    gates in the same family
  • without getting out of its guaranteed range of
    operation.
  •  
  • In cases where more than 10 gates are connected
    to the output of a single gate of this family,
    the output voltage levels will degrade and the
    gate will slow down.
  • Modern MOS logic families have a fan-out of about
    50,
  • since each gate must source or sink a current
    only during the transition from H to L or L to H.

29
Power Dissipation
30
Metric 4 Power Dissipation
  • Each gate is connected to a power supply VCC
  • Draws a certain amount of current during its
    operation.
  •  
  • Since each gate can be in a High state,
    Transition or Low state.
  • can distinguish 3 different currents drawn from
    power supply.
  • ICCH
  • ICCT
  • ICCL

31
TTL
  • In some older logic families, such as TTL, the
    transition current ICCT is negligible
  • in comparison to ICCH and ICCL.
  •  
  • Assuming that gate spends an approximately equal
    amount of time in the high and the low states and
    approximately no time in the transition state
  • ?
  • Thus the average power dissipation (product of
    average current and power supply voltage)
  • Power dissipation is measured in mW
  • for the TTL family 10mW

32
CMOS
  • In more modern technologies such as the CMOS
    family
  • the steady-state currents ICCH and ICCL are
    negligible in comparison with ICCT.
  • Since ICCT is relatively small the typical power
    dissipation of CMOS gates is small.
  • But the power dissipation increases with the
    frequency with which the gate output is changing

33
Power Dissipation
  • Power Dissipation is an important metric for two
    reasons.
  •  
  • Amount of current and power available in a
    battery is nearly constant.
  • power dissipation of a circuit or system defines
    battery life.
  • The greater the power dissipation, the shorter
    the battery life.
  •  
  •  
  • Power dissipation is proportional to the heat
    generated by the chip or system.
  • Excessive heat dissipation may increase operating
    temperature and cause gate circuitry to drift out
    of its normal operating range
  • will cause gates to generate improper output
    values.
  • Thus power dissipation of any gate implementation
    must be kept as low as possible

34
Propagation Delay
35
Metric 5 Propagation Delay
  • Propagation delay defined as
  •  
  • Average time needed for an input change to
    propagate to the output
  • Typically nanoseconds.
  • The propagation delay can be obtained from gate
    input and output waveforms.

36
Propagation Delay
  • Input and consequently output signal do not
    switch their values instantly
  • H ? L and L ? H changes can be delayed for
    different amounts of time
  •  
  •  
  • Since the signal values do not change instantly,
    define rise time
  • delay for a signal to switch from 10 to 90 of
    its nominal value.
  •  
  • Similarly define the fall time.
  • delay for a signal to switch from 90 to 10 of
    its nominal value.

37
Propagation Delay
  • Since H ? L and L ? H transitions are not delayed
    equally, can define
  •   tPHL H ? L propagation delay
  • tPLH L ? H propagation delay
  •  
  • tPHL is defined as
  • time necessary for output signal to reach 50 of
    its nominal value on H ? L transition after input
    signal reached 50 of its nominal value.
  • tPLH is defined similarly.
  •   
  • Propagation delay tP defined as average value of
    tPHL and tPHL.

38
Propagation Delay
  • 2-input NAND in the TTL family
  • tPHL 7 nsec
  • tPLH 11 nsec ? tp 9 nsec (711/2)
  •  
  • 2-input NAND in the CMOS family tp 1 nsec
  •  
  •  
  • As manufacturers cannot guarantee the same
    nominal value on every gate they fabricate
  • Usually give the maximum delay values (not that
    interested in the minimum delay)
  • no gate will exceed this maximal value.
  •   
  • 2-input NAND in the TTL family, the maximal
    propagation delays
  • tPHL 22 nsec
  • tPLH 15 nsec ? tp 18.5 nsec (2215/2)

39
Summary
  • Need to have metrics to allow Digital Designers
    compare different designs.
  • So either the cost effective or fastest design
    can be implemented for each application.
  • Lecture tonight
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