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Physical LayerPhysical Layer
PART IIPART II
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Position of the physical layer
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Services
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Chapters
Chapter 3 Signals
Chapter 4 Digital TransmissionChapter 5 Analog Transmission
Chapter 6 Multiplexing
Chapter 7 Transmission Media
Chapter 8 Circuit Switching and Telephone Network
Chapter 9 High Speed Digital Access
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Chapter 3
Signals
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To be transmitted, data must be transformed to electromagnetic
signals.
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3.1 Analog and Digital
Analog and Digital Data
Analog and Digital Signals
Periodic and Aperiodic Signals
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Signals can be analog or digital. Analog signals can have an infinite number of values in a range; digital
signals can have only a limited number of values.
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Figure 3.1 Comparison of analog and digital signals
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In data communication, we commonly use periodic analog signals and
aperiodic digital signals.
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3.2 Analog Signals
Sine WavePhaseExamples of Sine WavesTime and Frequency DomainsComposite SignalsBandwidth
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Figure 3.2 A sine wave
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Figure 3.3 Amplitude
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Frequency and period are inverses of each other.
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Figure 3.4 Period and frequency
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Table 3.1 Units of periods and frequenciesTable 3.1 Units of periods and frequencies
Unit Equivalent Unit Equivalent
Seconds (s) 1 s hertz (Hz) 1 Hz
Milliseconds (ms) 10–3 s kilohertz (KHz) 103 Hz
Microseconds (ms) 10–6 s megahertz (MHz) 106 Hz
Nanoseconds (ns) 10–9 s gigahertz (GHz) 109 Hz
Picoseconds (ps) 10–12 s terahertz (THz) 1012 Hz
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Example 1Example 1
Express a period of 100 ms in microseconds, and express the corresponding frequency in kilohertz.
SolutionSolution
From Table 3.1 we find the equivalent of 1 ms.We make the following substitutions:100 ms = 100 10-3 s = 100 10-3 10 s = 105 s
Now we use the inverse relationship to find the frequency, changing hertz to kilohertz100 ms = 100 10-3 s = 10-1 s f = 1/10-1 Hz = 10 10-3 KHz = 10-2 KHz
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Frequency is the rate of change with respect to time. Change in a short span of time means high frequency. Change
over a long span of time means low frequency.
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If a signal does not change at all, its frequency is zero. If a signal changes
instantaneously, its frequency is infinite.
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Phase describes the position of the waveform relative to time zero.
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Figure 3.5 Relationships between different phases
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Example 2Example 2
A sine wave is offset one-sixth of a cycle with respect to time zero. What is its phase in degrees and radians?
SolutionSolution
We know that one complete cycle is 360 degrees.
Therefore, 1/6 cycle is
(1/6) 360 = 60 degrees = 60 x 2 /360 rad = 1.046 rad
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Figure 3.6 Sine wave examples
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Figure 3.6 Sine wave examples (continued)
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Figure 3.6 Sine wave examples (continued)
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An analog signal is best represented in the frequency domain.
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Figure 3.7 Time and frequency domains
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Figure 3.7 Time and frequency domains (continued)
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Figure 3.7 Time and frequency domains (continued)
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A single-frequency sine wave is not useful in data communications; we need to change one or more of its characteristics to make it useful.
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When we change one or more When we change one or more characteristics of a single-frequency characteristics of a single-frequency signal, it becomes a composite signal signal, it becomes a composite signal
made of many frequencies.made of many frequencies.
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According to Fourier analysis, any composite signal can be represented as
a combination of simple sine waves with different frequencies, phases, and
amplitudes.
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Figure 3.8 Square wave
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Figure 3.9 Three harmonics
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Figure 3.10 Adding first three harmonics
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Figure 3.11 Frequency spectrum comparison
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Figure 3.12 Signal corruption
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The bandwidth is a property of a The bandwidth is a property of a medium: It is the difference between medium: It is the difference between
the highest and the lowest frequencies the highest and the lowest frequencies that the medium can that the medium can satisfactorily pass.satisfactorily pass.
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In this book, we use the term In this book, we use the term bandwidth to refer to the property of a bandwidth to refer to the property of a
medium or the width of a single medium or the width of a single spectrum.spectrum.
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Figure 3.13 Bandwidth
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Example 3Example 3
If a periodic signal is decomposed into five sine waves with frequencies of 100, 300, 500, 700, and 900 Hz, what is the bandwidth? Draw the spectrum, assuming all components have a maximum amplitude of 10 V.
SolutionSolutionB = fh fl = 900 100 = 800 HzThe spectrum has only five spikes, at 100, 300, 500, 700, and 900 (see Figure 13.4 )
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Figure 3.14 Example 3
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Example 4Example 4
A signal has a bandwidth of 20 Hz. The highest frequency is 60 Hz. What is the lowest frequency? Draw the spectrum if the signal contains all integral frequencies of the same amplitude.
SolutionSolution
B = fB = fhh f fll
20 = 60 20 = 60 ffll
ffll = 60 = 60 20 = 40 Hz20 = 40 Hz
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Figure 3.15 Example 4
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Example 5Example 5
A signal has a spectrum with frequencies between 1000 and 2000 Hz (bandwidth of 1000 Hz). A medium can pass frequencies from 3000 to 4000 Hz (a bandwidth of 1000 Hz). Can this signal faithfully pass through this medium?
SolutionSolution
The answer is definitely no. Although the signal can have The answer is definitely no. Although the signal can have the same bandwidth (1000 Hz), the range does not the same bandwidth (1000 Hz), the range does not overlap. The medium can only pass the frequencies overlap. The medium can only pass the frequencies between 3000 and 4000 Hz; the signal is totally lost.between 3000 and 4000 Hz; the signal is totally lost.
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3.3 Digital Signals3.3 Digital Signals
Bit Interval and Bit RateAs a Composite Analog SignalThrough Wide-Bandwidth MediumThrough Band-Limited MediumVersus Analog BandwidthHigher Bit Rate
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Figure 3.16 A digital signal
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Example 6Example 6
A digital signal has a bit rate of 2000 bps. What is the duration of each bit (bit interval)
SolutionSolution
The bit interval is the inverse of the bit rate.
Bit interval = 1/ 2000 s = 0.000500 s = 0.000500 x 106 s = 500 s
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Figure 3.17 Bit rate and bit interval
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Figure 3.18 Digital versus analog
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A digital signal is a composite signal A digital signal is a composite signal with an infinite bandwidth.with an infinite bandwidth.
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Table 3.12 Bandwidth RequirementTable 3.12 Bandwidth Requirement
BitRate
Harmonic1
Harmonics1, 3
Harmonics1, 3, 5
Harmonics1, 3, 5, 7
1 Kbps 500 Hz 2 KHz 4.5 KHz 8 KHz
10 Kbps 5 KHz 20 KHz 45 KHz 80 KHz
100 Kbps 50 KHz 200 KHz 450 KHz 800 KHz
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The bit rate and the bandwidth are The bit rate and the bandwidth are proportional to each other.proportional to each other.
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3.4 Analog versus Digital3.4 Analog versus Digital
Low-pass versus Band-pass
Digital Transmission
Analog Transmission
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Figure 3.19 Low-pass and band-pass
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The analog bandwidth of a medium is The analog bandwidth of a medium is expressed in hertz; the digital expressed in hertz; the digital bandwidth, in bits per second.bandwidth, in bits per second.
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Digital transmission needs a Digital transmission needs a low-pass channel.low-pass channel.
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Analog transmission can use a band-Analog transmission can use a band-pass channel.pass channel.
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3.5 Data Rate Limit3.5 Data Rate Limit
Noiseless Channel: Nyquist Bit Rate
Noisy Channel: Shannon Capacity
Using Both Limits
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Example 7Example 7
Consider a noiseless channel with a bandwidth of 3000 Hz transmitting a signal with two signal levels. The maximum bit rate can be calculated as
BitBit Rate = 2 Rate = 2 3000 3000 log log22 2 = 6000 bps 2 = 6000 bps
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Example 8Example 8
Consider the same noiseless channel, transmitting a signal with four signal levels (for each level, we send two bits). The maximum bit rate can be calculated as:
Bit Rate = 2 x 3000 x logBit Rate = 2 x 3000 x log22 4 = 12,000 bps 4 = 12,000 bps
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Example 9Example 9
Consider an extremely noisy channel in which the value of the signal-to-noise ratio is almost zero. In other words, the noise is so strong that the signal is faint. For this channel the capacity is calculated as
C = B logC = B log22 (1 + SNR) = B log (1 + SNR) = B log22 (1 + 0) (1 + 0)
= B log= B log22 (1) = B (1) = B 0 = 0 0 = 0
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Example 10Example 10
We can calculate the theoretical highest bit rate of a regular telephone line. A telephone line normally has a bandwidth of 3000 Hz (300 Hz to 3300 Hz). The signal-to-noise ratio is usually 3162. For this channel the capacity is calculated as
C = B logC = B log22 (1 + SNR) = 3000 log (1 + SNR) = 3000 log22 (1 + 3162) (1 + 3162) = 3000 log= 3000 log22 (3163) (3163)
C = 3000 C = 3000 11.62 = 34,860 bps 11.62 = 34,860 bps
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Example 11Example 11
We have a channel with a 1 MHz bandwidth. The SNR for this channel is 63; what is the appropriate bit rate and signal level?
SolutionSolution
C = B logC = B log22 (1 + SNR) = 10 (1 + SNR) = 1066 log log22 (1 + 63) = 10 (1 + 63) = 1066 log log22 (64) = 6 Mbps (64) = 6 Mbps
Then we use the Nyquist formula to find the number of signal levels.
4 Mbps = 2 4 Mbps = 2 1 MHz 1 MHz log log22 LL L = 4 L = 4
First, we use the Shannon formula to find our upper First, we use the Shannon formula to find our upper limit.limit.
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3.6 Transmission Impairment3.6 Transmission Impairment
Attenuation
Distortion
Noise
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Figure 3.20 Impairment types
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Figure 3.21 Attenuation
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Example 12Example 12
Imagine a signal travels through a transmission medium and its power is reduced to half. This means that P2 = 1/2 P1. In this case, the attenuation (loss of power) can be calculated as
SolutionSolution
10 log10 log1010 (P2/P1) = 10 log (P2/P1) = 10 log1010 (0.5P1/P1) = 10 log (0.5P1/P1) = 10 log1010 (0.5) (0.5) = 10(–0.3) = –3 dB = 10(–0.3) = –3 dB
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Example 13Example 13
Imagine a signal travels through an amplifier and its power is increased ten times. This means that P2 = 10 ¥ P1. In this case, the amplification (gain of power) can be calculated as
10 log10 log1010 (P2/P1) = 10 log (P2/P1) = 10 log1010 (10P1/P1) (10P1/P1)
= 10 log= 10 log1010 (10) = 10 (1) = 10 dB (10) = 10 (1) = 10 dB
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Example 14Example 14
One reason that engineers use the decibel to measure the changes in the strength of a signal is that decibel numbers can be added (or subtracted) when we are talking about several points instead of just two (cascading). In Figure 3.22 a signal travels a long distance from point 1 to point 4. The signal is attenuated by the time it reaches point 2. Between points 2 and 3, the signal is amplified. Again, between points 3 and 4, the signal is attenuated. We can find the resultant decibel for the signal just by adding the decibel measurements between each set of points.
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Figure 3.22 Example 14
dB = –3 + 7 – 3 = +1
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Figure 3.23 Distortion
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Figure 3.24 Noise
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3.7 More About Signals3.7 More About Signals
Throughput
Propagation Speed
Propagation Time
Wavelength
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Figure 3.25 Throughput
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Figure 3.26 Propagation time
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Figure 3.27 Wavelength