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Title: Side Arrows Background


1
Lecture 15
Computer Communication Networks
2
  • Todays Menu
  • Encoding/Decoding
  • Unipolar, Polar and Bipolar encoding

3
Encoding/Decoding
  • Digital-to-Digital conversion or
    encoding/decoding is the representation of
    digital information by digital signal
  • For example when we transmit data from computer
    to the printer, both original and transmitted
    data have to be digital
  • Encoding a digital signal is where 1s and 0s
    generated by the computer are translated into
    voltage pulses that can be propagated over the
    wire

4
Encoding/Decoding
5
Encoding/Decoding
  • A digital signal is a sequence of discrete,
    discontinuous voltage pulses, each pulse is a
    signal element
  • Binary data are transmitted by encoding each data
    bit into signal elements
  • In the simplest case, there is a one-to-one
    correspondence between bits and signal elements
  • An example would be in which binary 0 is
    represented by a lower voltage level and binary 1
    by a higher voltage level
  • A variety of other encoding schemes are also used

6
Encoding/Decoding
  • Types of Encoding
  • Unipolar
  • Polar
  • Bipolar
  • 1-Unipolar
  • Encoding is simple , with only one technique in
    use
  • Simple and primitive
  • Almost obsolete today
  • Study provides introduction to concepts and
    problems involved with more complex encoding
    systems

7
Unipolar Encoding
  • It works by sending voltage pulses on the
    transmission medium
  • The signal elements all have the same algebraic
    sign, that is, all positive or negative
  • One voltage level stands for binary 0 while the
    other stands for binary 1
  • It is called Unipolar because it uses only one
    polarity
  • This polarity is assigned to one of the two
    binary states usually a 1
  • The other state usually a 0 is represented by
    zero voltage

8
Unipolar Encoding
  • Figure shows the idea 1s are encoded as ve
    values, and 0s are encoded as ve values

9
Unipolar Encoding
  • Pros and Cons of Unipolar Encoding
  • Pros
  • Straight forward and simple
  • Inexpensive to implement
  • Cons
  • DC component
  • Synchronization

10
Polar Encoding
  • 2-Polar
  • Polar encoding uses two voltage levels, positive
    and negative
  • One logic state is represented by a positive
    voltage level, and the other by a negative
    voltage level
  • It has 3 subcategories
  • Non Return to Zero (NRZ)
  • NRZL
  • NRZI
  • Return to Zero (RZ)
  • Biphase
  • Manchester
  • Differential Manchester

11
Polar Encoding
12
Non Return to Zero (NRZ)
  • In NRZ, the level of signal is either positive or
    negative
  • NRZ-L (Non-Return-to-Zero-Level)
  • Level of the signal depends on the type of bit it
    represents
  • A ve voltage usually means the bit is a 1 and a
    ve voltage means the bit is a 0 (vice versa)

13
Non Return to Zero (NRZ)
Problem with NRZ-L When long streams of 0s
or 1s are there in data, receiver receives a
continuous voltage and should determine how many
bits are sent by relying on its clock, which may
or may not be synchronized with the sender clock
14
Non Return to Zero (NRZ)
  • NRZ-I (Non-Return-to-Zero-Invert On One)
  • The inversion of the level represents a 1 bit
  • A bit 0 is represented by no change
  • A transition (low-to-high or high-to-low) at the
    beginning of a bit time denotes a binary 1 for
    that bit time no transition indicates a binary 0

15
Non Return to Zero (NRZ)
  • Problem with NRZ-I
  • NRZ-I is superior to NRZ-L due to synchronization
    provided by signal change each time a 1 bit is
    encountered
  • The string of 0s can still cause problem but
    since 0s are not as likely, they are less of a
    problem

16
Non Return to Zero (NRZ)
  • The NRZ codes are the easiest to engineer and, in
    addition, make efficient use of bandwidth
  • The main limitations of NRZ signals are the
    presence of a dc component and the lack of
    synchronization capability
  • Because of their simplicity and relatively low
    frequency response characteristics, NRZ codes are
    commonly used for digital magnetic recording
  • However, their limitations make these codes
    unattractive for signal transmission applications

17
Return to Zero (RZ)
  • Any time, data contains long strings of 1s or
    0s, receiver can loose its timing
  • In unipolar, we have seen a good solution is to
    send a separate timing signal but this solution
    is expensive
  • A better solution is to somehow include sync in
    encoded signal somewhat similar to what we did in
    NRZ-I but it should work for both strings of 0
    1
  • One solution is RZ encoding which uses 3 values
    Positive, Negative and Zero
  • Signal changes not between bits but during each
    bit

18
Return to Zero (RZ)
  • Like NRZ-L, ve voltage means 1 and a ve voltage
    means 0, but unlike NRZ-L, half way through each
    bit interval, the signal returns to zero
  • A 1 bit is represented by positive to zero and a
    0 is represented by negative to zero transition

19
Return to Zero (RZ)
  • Problem with RZ
  • The only problem with RZ encoding is that it
    requires two signal changes to encode one bit and
    therefore occupies more bandwidth
  • But of the 3 alternatives we have discussed, it
    is most effective

20
Biphase
  • Best existing solution to the problem of
    synchronization
  • Signal changes at the middle of bit interval but
    does not stop at zero
  • Instead it continues to the opposite pole
  • There are two types of biphase encoding
  • Manchester
  • Differential Manchester

21
Manchester
  • Uses inversion at the middle of each bit interval
    for both synchronization and bit representation
  • Negative-to-Positive
    Transition 1
  • Positive-to-Negative
    Transition 0
  • By using a single transition for a dual purpose,
    Manchester achieves the same level of
    synchronization as RZ but with only two levels of
    amplitude

22
Differential Manchester
  • Inversion at the middle of the bit interval is
    used for synchronization but presence or absence
    of an additional transition at the beginning of
    bit interval is used to identify a bit
  • A transition means binary 0 no transition means
    binary 1
  • Requires 2 signal changes to represent binary 0
    but only one to represent binary 1

23
3-Bipolar Encoding
  • Although the biphase techniques have achieved
    widespread use in local-area-network applications
    at relatively high data rates, they have not been
    widely used in long-distance applications
  • The principal reason for this is that they
    require a high signaling rate relative to the
    data rate
  • This sort of inefficiency is more costly in a
    long-distance application

24
Bipolar Encoding
  • An approach is to make use of some sort of
    scrambling scheme
  • The idea behind this approach is simple
  • Sequences that would result in a constant voltage
    level on the line are replaced by filling
    sequences that will provide sufficient
    transitions for the receiver's clock to maintain
    synchronization
  • The filling sequence must be recognized by the
    receiver and replaced with the original data
    sequence

25
Bipolar Encoding
  • Like RZ, it uses three voltage levels
  • Unlike RZ, zero level is used to represent binary
    0
  • Binary 1s are represented by alternate positive
    and negative voltages
  • AMI
  • Pseudoternary
  • B8Zs
  • HDB3

26
Alternate Mark Inversion(AMI)
  • Simplest type of bipolar encoding
  • A binary 0 is represented by no line signal, and
    a binary 1 is represented by a positive or
    negative pulse
  • The binary 1 pulses must alternate in polarity
  • Alternate Mark Inversion means alternate 1
    inversion

27
Alternate Mark Inversion(AMI)
  • Pros and Cons
  • There will be no loss of synchronization if a
    long string of is occurs
  • Each 1 introduces a transition, and the receiver
    can resynchronize on that transition
  • A long string of 0s would still be a problem
  • Because the 1 signals alternate in voltage from
    positive to negative, there is no net dc component

28
Pseudoternary
  • Inverse of AMI
  • In this case, it is the binary 1 that is
    represented by the absence of a line signal, and
    the binary 0 by alternating positive and negative
    pulses

29
Pseudoternary
  • Two variations are developed to solve the problem
    of synchronization of sequential 0s
  • B8Zs (used in North America)
  • HDB3 (used in Europe Japan)
  • Both modify original pattern of AMI only on case
    of long stream of zeroes

30
B8Zs
  • Bipolar with 8-zeros substitution
  • Difference between AMI and B8Zs occurs only when
    8 or more consecutive zeros are encountered
  • Forces artificial signal changes called
    violations
  • Each time eight 0s occur, B8Zs introduces
    changes in pattern based on polarity of previous
    1 (the 1 occurring just before zeros)
  • Same as bipolar AMI, except that any string of
    eight zeros is replaced by a string with two code
    violations

31
B8Zs
32
HDB3
  • High-Density Bipolar-3 Zeros
  • Alteration of AMI adopted in Europe and Japan
  • Introduces changes into AMI, every time four
    consecutive zeros are encountered instead of
    waiting for eight zeros as in the case of B8Zs
  • As in B8Zs, the pattern of violations is based on
    the polarity of the previous 1 bit
  • HDB3 also looks at the number of 1s that have
    occurred since the last substitution
  • Same as bipolar AMI, except that any string of
    four zeros is replaced by a string with one code
    violation

33
HDB3
  • High-Density Bipolar-3 Zeros

34
HDB3
  • High-Density Bipolar-3 Zeros
  • If the last violation was positive, this
    violation must be negative, and vice versa
  • The table shows that this condition is tested for
    by knowing whether the number of pulses since the
    last violation is even or odd and the polarity of
    the last pulse before the occurrence of the four
    zeros

35
HDB3
  • High-Density Bipolar-3 Zeros
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