CWNA Guide to Wireless LANs, Second Edition

Chapter FourIEEE 802.11 Physical Layer Standards

CWNA Guide to Wireless LANs, Second Edition 2

Objectives

• List and describe the wireless modulation schemes used in IEEE WLANs

• Tell the difference between frequency hopping spread spectrum and direct sequence spread spectrum

• Explain how orthogonal frequency division multiplexing is used to increase network throughput

• List the characteristics of the Physical layer standards in 802.11b, 802.11g, and 802.11a networks

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Introduction

Figure 4-2: OSI data flow

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Introduction (continued)

Table 4-1: OSI layers and functions

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Wireless Modulation Schemes

• Four primary wireless modulation schemes:– Narrowband transmission– Frequency hopping spread spectrum– Direct sequence spread spectrum– Orthogonal frequency division multiplexing

• Narrowband transmission used primarily by radio stations

• Other three used in IEEE 802.11 WLANs

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Narrowband Transmission

• Radio signals by nature transmit on only one radio frequency or a narrow portion of frequencies

• Require more power for the signal to be transmitted – Signal must exceed noise level

• Total amount of outside interference

• Vulnerable to interference from another radio signal at or near same frequency

• IEEE 802.11 standards do not use narrowband transmissions

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Narrowband Transmission (continued)

Figure 4-3: Narrowband transmission

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Spread Spectrum Transmission

Figure 4-4: Spread spectrum transmission

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Spread Spectrum Transmission (continued)

• Advantages over narrowband:– Resistance to narrowband interference– Resistance to spread spectrum interference– Lower power requirements– Less interference on other systems– More information transmitted– Increased security– Resistance to multipath distortion

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Frequency Hopping Spread Spectrum (FHSS)

• Uses range of frequencies – Change during transmission

• Hopping code: Sequence of changing frequencies– If interference encountered on particular frequency

then that part of signal will be retransmitted on next frequency of hopping code

• FCC has established restrictions on FHSS to reduce interference

• Due to speed limitations FHSS not widely implemented in today’s WLAN systems– Bluetooth does use FHSS

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Frequency Hopping Spread Spectrum (continued)

Figure 4-6: FHSS error correction

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Direct Sequence Spread Spectrum (DSSS)

• Uses expanded redundant code to transmit data bits

• Chipping code: Bit pattern substituted for original transmission bits– Advantages of using DSSS with a chipping code:

• Error correction

• Less interference on other systems

• Shared frequency bandwidth

– Co-location: Each device assigned unique chipping code

• Security

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Direct Sequence Spread Spectrum (continued)

Figure 4-7: Direct sequence spread spectrum (DSSS) transmission

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Orthogonal Frequency Division Multiplexing (OFDM)

• With multipath distortion, receiving device must wait until all reflections received before transmitting– Puts ceiling limit on overall speed of WLAN

• OFDM: Send multiple signals at same time– Split high-speed digital signal into several slower

signals running in parallel

• OFDM increases throughput by sending data more slowly

• Avoids problems caused by multipath distortion

• Used in 802.11a networks

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Orthogonal Frequency Division Multiplexing (continued)

Figure 4-8: Multiple channels

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Orthogonal Frequency Division Multiplexing (continued)

Figure 4-9: Orthogonal frequency division multiplexing (OFDM) vs. single-channel transmissions

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Comparison of Wireless Modulation Schemes

• FHSS transmissions less prone to interference from outside signals than DSSS

• WLAN systems that use FHSS have potential for higher number of co-location units than DSSS

• DSSS has potential for greater transmission speeds over FHSS

• Throughput much greater for DSSS than FHSS– Amount of data a channel can send and receive

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Comparison of Wireless Modulation Schemes (continued)

• DSSS preferred over FHSS for 802.11b WLANs

• OFDM is currently most popular modulation scheme– High throughput– Supports speeds over 100 Mbps for 802.11a WLANs – Supports speeds over 54 Mbps for 802.11g WLANs

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IEEE 802.11 Physical Layer Standards

• IEEE wireless standards follow OSI model, with some modifications

• Data Link layer divided into two sublayers:– Logical Link Control (LLC) sublayer: Provides

common interface, reliability, and flow control– Media Access Control (MAC) sublayer: Appends

physical addresses to frames

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IEEE 802.11 Physical Layer Standards (continued)

• Physical layer divided into two sublayers:– Physical Medium Dependent (PMD) sublayer:

Makes up standards for characteristics of wireless medium (such as DSSS or FHSS) and defines method for transmitting and receiving data

– Physical Layer Convergence Procedure (PLCP) sublayer: Performs two basic functions

• Reformats data received from MAC layer into frame that PMD sublayer can transmit

• “Listens” to determine when data can be sent

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IEEE 802.11 Physical Layer Standards (continued)

Figure 4-10: Data Link sublayers

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IEEE 802.11 Physical Layer Standards (continued)

Figure 4-11: PHY sublayers

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IEEE 802.11 Physical Layer Standards (continued)

Figure 4-12: PLCP sublayer reformats MAC data

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IEEE 802.11 Physical Layer Standards (continued)

Figure 4-13: IEEE LANs share the same LLC

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Legacy WLANs

• Two “obsolete” WLAN standards: – Original IEEE 802.11: FHSS or DSSS could be used

for RF transmissions• But not both on same WLAN

– HomeRF: Based on Shared Wireless Access Protocol (SWAP)

• Defines set of specifications for wireless data and voice communications around the home

• Slow

• Never gained popularity

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IEEE 802.11b Physical Layer Standards

• Physical Layer Convergence Procedure Standards: Based on DSSS– PLCP must reformat data received from MAC layer

into a frame that the PMD sublayer can transmit

Figure 4-14: 802.11b PLCP frame

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IEEE 802.11b Physical Layer Standards (continued)

• PLCP frame made up of three parts:– Preamble: prepares receiving device for rest of

frame– Header: Provides information about frame– Data: Info being transmitted

• Synchronization field• Start frame delimiter field• Signal data rate field• Service field• Length field• Header error check field• Data field

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IEEE 802.11b Physical Layer Standards (continued)

• Physical Medium Dependent Standards: PMD translates binary 1’s and 0’s of frame into radio signals for transmission– Can transmit at 11, 5.5, 2, or 1 Mbps– 802.11b uses ISM band

• 14 frequencies can be used

– Two types of modulation can be used• Differential binary phase shift keying (DBPSK): For

transmissions at 1 Mbps

• Differential quadrature phase shift keying (DQPSK): For transmissions at 2, 5.5, and 11 Mbps

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IEEE 802.11b Physical Layer Standards (continued)

Table 4-2: 802.11b ISM channels

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IEEE 802.11b Physical Layer Standards (continued)

Table 4-3: IEEE 802.11b Physical layer standards

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IEEE 802.11a Physical Layer Standards

• IEEE 802.11a achieves increase in speed and flexibility over 802.11b primarily through OFDM– Use higher frequency– Accesses more transmission channels– More efficient error-correction scheme

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U-NII Frequency Band

Table 4-5: U-NII characteristics

Table 4-4: ISM and U-NII WLAN characteristics

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U-NII Frequency Band (continued)

• Total bandwidth available for IEEE 802.11a WLANs using U-NII is almost four times that available for 802.11b networks using ISM band

• Disadvantages:– In some countries outside U.S., 5 GHz bands

allocated to users and technologies other than WLANs

– Interference from other devices is growing• Interference from other devices one of primary

sources of problems for 802.11b and 802.11a WLANs

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Channel Allocation

Figure 4-16: 802.11a channels

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Channel Allocation (continued)

Figure 4-17: 802.11b vs. 802.11a channel coverage

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Error Correction

• 802.11a has fewer errors than 802.11b– Transmissions sent over parallel subchannels– Interference tends to only affect one subchannel

• Forward Error Correction (FEC): Transmits secondary copy along with primary information– 4 of 52 channels used for FEC– Secondary copy used to recover lost data

• Reduces need for retransmission

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Physical Layer Standards

• PLCP for 802.11a based on OFDM• Three basic frame components: Preamble, header,

and data

Figure 4-18: 802.11a PLCP frame

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Physical Layer Standards (continued)

Table 4-6: 802.11a Rate field values

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Physical Layer Standards (continued)

• Modulation techniques used to encode 802.11a data vary depending upon speed

• Speeds higher than 54 Mbps may be achieved using 2X modes

Table 4-7: 802.11a characteristics

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Physical Layer Standards (continued)

Figure 4-19: Phase shift keying (PSK)

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Physical Layer Standards (continued)

Figure 4-20: Quadrature phase shift keying (QPSK)

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Physical Layer Standards (continued)

Figure 4-21: 16-level quadrature amplitude modulation (16-QAM)

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Physical Layer Standards (continued)

Figure 4-22: 64-level quadrature amplitude modulation (64-QAM)

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IEEE 802.11g Physical Layer Standards

• 802.11g combines best features of 802.11a and 802.11b

• Operates entirely in 2.4 GHz ISM frequency

• Two mandatory modes and one optional mode– CCK mode used at 11 and 5.5 Mbps (mandatory)– OFDM used at 54 Mbps (mandatory)– PBCC-22 (Packet Binary Convolution Coding):

Optional mode• Can transmit between 6 and 54 Mbps

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IEEE 802.11g Physical Layer Standards (continued)

Table 4-8: IEEE 802.11g Physical layer standards

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IEEE 802.11g Physical Layer Standards (continued)

• Characteristics of 802.11g standard:– Greater throughput than 802.11b networks – Covers broader area than 802.11a networks– Backward compatible– Only three channels– If 802.11b and 802.11g devices transmitting in same

environment, 802.11g devices drop to 11 Mbps speeds

– Vendors can implement proprietary higher speed• Channel bonding and Dynamic turbo

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Summary

• Three modulation schemes are used in IEEE 802.11 wireless LANs: frequency hopping spread spectrum (FHSS), direct sequence spread spectrum (DSSS), and orthogonal frequency division multiplexing (OFDM)

• Spread spectrum is a technique that takes a narrow, weaker signal and spreads it over a broader portion of the radio frequency band

• Spread spectrum transmission uses two different methods to spread the signal over a wider area: FHSS and DSSS

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Summary (continued)

• OFDM splits a single high-speed digital signal into several slower signals running in parallel

• IEEE has divided the OSI model Data Link layer into two sublayers: the LLC and MAC sublayers

• The Physical layer is subdivided into the PMD sublayer and the PLCP sublayer

• The Physical Layer Convergence Procedure Standards (PLCP) for 802.11b are based on DSSS

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Summary (continued)

• IEEE 802.11a networks operate at speeds up to 54 Mbps with an optional 108 Mbps

• The 802.11g standard specifies that it operates entirely in the 2.4 GHz ISM frequency and not the U-NII band used by 802.11a