Wireless Communications - PowerPoint PPT Presentation

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Wireless Communications

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BPSK 0 degree when `0 , 180 degree when `1 . Basic Wireless System The very basic wireless communication system Sender: given the bit stream, ... – PowerPoint PPT presentation

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Title: Wireless Communications


1
Wireless Communications
2
Wireless Communications
  • Wireless is more and more widely deployed
    cellphone, wireless LAN,
  • The fundamental fact is that if the sender sends
    a sine wave, the receiver will receive a sine
    wave at the same frequency. But with
  • A different phase
  • A new amplitude
  • How do you design communication schemes based on
    that?

3
Wireless Communications
  • AM stronger signal when 1, weaker signal when
    0.
  • FM faster waveform when 1, slower signal when
    0.
  • BPSK 0 degree when 0, 180 degree when 1.

4
Basic Wireless System
  • The very basic wireless communication system
  • Sender given the bit stream, convert it to the
    baseband waveform by a Low Pass Filter, then
    multiply with the carrier waveform (2.4GHz if
    802.11g, 1.8GHz if some cellphones), and send.
  • Receiver given the signal received from the
    antenna, multiply it with a locally generated
    carrier, send it to the low pass filter,
    regenerate the baseband waveform.

5
Basic Wireless System
  • The sender cannot send the square waveform but
    has to send I(t) which is bandwidth limited from
    0Hz to some cutoff frequency BHz. The signal in
    the air in this simple system occupies frequency
    range f-B,fB.
  • Because cos(2pf1t)cos(2pft) cos2p(f1tf)t
    cos2p(f1-f)t (constant dropped). So basically
    one frequency in the baseband will become two
    frequencies.
  • The f-B,fB must be within the frequency band
    allocated for this system (around 20MHz in
    802.11g, around 25MHz in GSM) because the medium
    is shared

6
Basic Wireless System
  • How can the receiver regenerate the baseband
    waveform? A simplified explanation
  • The sender sends I(t)cos(2pft).
  • Assume there is no phase difference, the receiver
    multiplies I(t)cos(2pft) with cos(2pft), and gets
  • I(t)cos2(2pft) I(t)1/2 1/2cos(4pft).
  • Then, after the low pass filter, what is left is
    the low frequency component I(t).
  • http//math2.org/math/trig/identities.htm

7
Two Orthogonal Channels
  • The sender sends I(t)cos(2pft) Q(t)sin(2pft).
  • The receiver multiplies the received signal with
    cos(2pft) , and will get
  • I(t)cos(2pft) Q(t)sin(2pft) cos(2pft)
    I(t)1cos(4pft) Q(t) sin(4pft)
  • (constant dropped), and after the LPF, will have
    I(t).
  • At the same time, the receiver also multiplies
    the received signal with sin(2pft) , and will get
  • I(t)cos(2pft) Q(t)sin(2pft) sin(2pft) I(t)
    sin(4pft) Q(t) 1-cos(4pft)
  • (constant dropped), and after the LPF, will have
    Q(t).
  • So, the sender can send TWO baseband waveforms at
    the same time. Each baseband waveform can carry
    one voltage value, so a symbol is a point on the
    two-dimensional plane. We often use a complex
    number to represent the symbol, where the value
    in I(t) is the real part and the value in Q(t) is
    the imaginary part.

8
BPSK, QPSK, QAM
  • BPSK is using only one channel. And in this
    channel, only two possible voltages.
  • Quadrature phase-shift keying (QPSK) is using
    both channels. In each channel, only two
    voltages.
  • Quadrature amplitude modulation (QAM) is using
    both channels. In each channel, multiple
    voltages. If 4 levels of voltage, it is 16QAM. If
    it 8 levels of voltage, 64QAM.

9
After Getting the Baseband Signal
  • The baseband signal is a continuous waveform.
  • You have to run an algorithm on that to convert
    the continuous waveform into bits.
  • Main constraint of the algorithm should run
    very fast, i.e., capable of making a decision
    every symbol time, must be implemented in
    hardware, cost is issue.

10
Issues
  • How to offset the phase difference from the
    sender to the receiver?
  • How to take samples at the right time?
  • How to get rid of the residual values from nearby
    symbols, i.e., dealing with multipath?
  • In wireless channels, when the sender sends one
    waveform, the receiver will receive many copies
    of it, with different phase offset, because the
    signal travels multiple paths with reflecting
    surfaces like the metal door, wall, etc.
  • When taking a sample, the sample could be the
    best for the strongest path, but may not be for
    other paths. So some residual voltage from the
    previous symbol will show up.

11
Exercise
  • Consider an 802.11g device A transmitting at
    channel 1 which is 2.412GHz. There is another
    802.11g device B tuned to channel 6 which is
    2.437GHz. Assume B is in transmission range of A.
    Why wont B respond to As transmission?
  • (a).Because Bs antenna cannot respond to
    waveforms centered at 2.412GHz.
  • (b).Because Bs local sine wave is at 2.437GHz,
    and after multiplying it with the received
    waveform, the result is 0.
  • (c). Because Bs upper layer software will filter
    out packets from other channels.
  • (d). None of the above.

12
Exercise
  • An 802.11g channel has bandwidth of 22MHz. Which
    of the following statements is true?
  • (a).Due to the bandwidth constraint, the highest
    data rate of 802.11g cannot be more than 22Mbps.
  • (b).The bandwidth constraint limits the highest
    achievable speed, but the actual speed also
    depends on the strength of the channel.
  • (c). An 802.11g transmitter transmits at the
    center of the channel frequency so the bandwidth
    limit has no effect on the speed.
  • (d). None of the above.

13
Exercise
  • Which of the following statements about the
    baseband signal is true?
  • (a). The baseband signal refers to the signal
    after the low pass filer.
  • (b). The baseband signal is bandwidth-limited.
  • (c). Both of the above.
  • (d). None of the above.

14
Exercise
  • In wireless transmissions, we often use the terms
    sample and symbol. Which of the following
    statements is true?
  • (a). A symbol is a complex number. A BPSK symbol
    is either -1 or 1.
  • (b). A sample is a complex number. A BPSK sample
    is either -1 or 1.
  • (c). Both of the above.
  • (d). None of the above.

15
Exercise
  • With GNU Software Defined Radio, the transmitter
    and the receiver can operate at 500K symbols per
    second. Which of the following statement is true?
  • (a).It means that we can send one symbol per 2
    microseconds.
  • (b).It means that our data rate is 1Mbps if we
    use QPSK.
  • (c).Both of the above.
  • (d). None of the above.

16
Some Important Concepts
  • Bandwidth How fast can signals change. Or, the
    width of the frequency range that can pass the
    system.
  • Noise Will be added to the signal. Random, but
    some statistics can be known with which we make
    our detection rules.
  • Data rate How fast can we send bits, can be
    measured in bps. Upper bounded by the Shannons
    theorem given the bandwidth and noise.
  • Propagation delay How long does it take for the
    symbol to reach to the destination.
  • Symbol A point on the plane to represent one
    bit or multiple bits.
  • Sample A reading of the received signal at some
    time instant. Usually a corrupted version of the
    symbol.
  • Filter Some device or software that can remove
    certain frequency components in the received
    waveform.
  • Carrier A sine wave to be multiplied with the
    baseband waveform.
  • Baseband waveform The waveform that is a
    smoothed version of the square waveform after the
    low pass filter. To be multiplied with the
    carrier.
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