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An Introduction to Computer Networks

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Title: An Introduction to Computer Networks


1
An Introduction to Computer Networks
Lecture 8 Wirless Networks
  • University of Tehran
  • Dept. of EE and Computer Engineering
  • By
  • Dr. Nasser Yazdani

2
Outline
  • Why wireless Networks
  • What is special on wireless networks
  • Challenges
  • Bluetooth
  • Zigbee
  • 802.11
  • 802.11 mac

3
Why wireless networks?
  • Mobility to support mobile applications
  • Costs reductions in infrastructure and operating
    costs no cabling or cable replacement
  • Special situations No cabling is possible or it
    is very expensive.
  • Reduce downtime Moisture or hazards may cut
    connections.

4
Why wireless networks? (cont)
  • Rapidly growing market attests to public need for
    mobility and uninterrupted access
  • Consumers are used to the flexibility and will
    demand instantaneous, uninterrupted, fast access
    regardless of the application.
  • Consumers and businesses are willing to pay for
    it

5
The Two Hottest Trends inTelecommunications
Networks
Millions
Mobile Telephone Users
Internet Users
Year
Source Ericsson Radio Systems, Inc.
6
Growth of Home wireless
7
Why is it so popular?
  • Flexible
  • Low cost
  • Easy to deploy
  • Support mobility

8
Applications ?
  • Ubiquitous, Pervasive computing or nomadic
    access.
  • Ad hoc networking Where it is difficult or
    impossible to set infrastructure.
  • LAN extensions Robots or industrial equipment
    communicate each others. Sensor network where
    elements are two many and they can not be wired!.
  • Sensor Networks for monitoring, controlling, e

9
Ad hoc networks
  • Collection of wireless mobile nodes dynamically
    forming a temporary network without the use of
    any existing network infrastructure or
    centralized administration.
  • Hop-by-hop routing due to limited range of each
    node
  • Nodes may enter and leave the network
  • Usage scenarios
  • Military
  • Disaster relief
  • Temporary groups of participants (conferences)

10
Sensor networks
  • Deployment of small, usually wireless sensor
    nodes.
  • Collect data, stream to central site
  • Maybe have actuators
  • Hugely resource constrained
  • Internet protocols have implicit assumptions
    about node capabilities
  • Power cost to transmit each bit is very high
    relative to node battery lifetime
  • Loss / etc., like other wireless
  • Ad-hoc Deployment is often somewhat random

11
Wireless Applications
12
Summary
  • Need to be connected from everywhere and anytime.
  • Need to be connected on movement
  • Need to good quality service on those situation.
  • Interworking with the existing networks

13
Classification of Wireless Networks
  • Mobility fixed wireless or mobile
  • Analog or digital
  • Ad hoc (decentralized) or centralized (fixed base
    stations)
  • Services voice (isochronous) or data
    (asynchronous)
  • Ownership public or private

14
Classification of Wireless Networks
  • Area wide (WAN), metropolitan (MAN), local
    (LAN), or personal (PAN) area networks
  • Switched (circuit- or packet-switched) or
    broadcast
  • Low bit-rate (voice grade) or high bit-rate
    (video, multimedia)
  • Terrestrial or satellite

15
What is special on wireless?
  • Mobility in the network elements
  • Very diverse applications/devices.
  • Connectivity and coverage (internetworking) is a
    problem.
  • Maintaining quality of service over very
    unreliable links
  • Security (privacy, authentication,...) is very
    serious here. Broadcast media.
  • Cost efficiency

16
Big issues!
  • Integration with existing data networks sounds
    very difficult.
  • It is not always possible to apply wired networks
    design methods/principles here.
  • Layering is not work very well, mostly we need
    cross layer design

17
Wireless Differences 1
  • Physical layer signals travel in open space
  • Subject to interference
  • From other sources and self (multipath)
  • Creates interference for other wireless devices
  • Noisy ? lots of losses
  • Channel conditions can be very dynamic

18
Wireless Differences 2
  • Need to share airwaves rather than wire
  • Dont know what hosts are involved
  • Hosts may not be using same link technology
  • Interaction of multiple transmitters at receiver
  • Collisions, capture, interference
  • Use of spectrum limited resource.
  • Cannot create more capacity very easily
  • More pressure to use spectrum efficiently

19
Wireless Differences 3
  • Mobility
  • Must update routing protocols to handle frequent
    changes
  • Requires hand off as mobile host moves in/out
    range
  • Changes in the channel conditions.
  • Coarse time scale distance/interference/obstacles
    change
  • Other characteristics of wireless
  • Slow

20
Growing Application Diversity
Collision AvoidanceCar Networks
Mesh Networks
Wired Internet
Access Point
Sensor
Relay Node
Ad-Hoc/Sensor Networks
Wireless Home Multimedia
21
Challenge Diversity
Wireless Edge Network
INTERNET
INTERNET
Wireless Edge Network
2005
2010
  • New architectures must accommodate rapidly
    evolving technology
  • Must accommodate different optimization goals
  • Power, coverage, capacity, price

22
Other Challenges
  • Performance Nothing is really work well
  • Security It is a broadcast media
  • Cross layer interception
  • TCP performance

23
Ideal Wireless Area network?
  • Wish List
  • High speed (Efficiency)
  • Low cost
  • No use/minimal use of the mobile equipment
    battery
  • Can work in the presence of other WLAN
    (Heterogeneity)
  • Easy to install and use
  • Etc

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Wireless LAN Design Goals
  • Wireless LAN Design Goals
  • Portable product Different countries have
    different regulations concerning RF band usage.
  • Low power consumption
  • License free operation
  • Multiple networks should co-exist

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Wireless LAN Design Alternatives
  • Design Choices
  • Physical Layer diffused Infrared (IR) or Radio
    Frequency (RF)?
  • Radio Technology Direct-Sequence or
    Frequency-Hopping?
  • Which frequency range to use?
  • Which MAC protocol to use.
  • Peer-Peer architecture or Base-Station approach?

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DSSS (Direct Sequence Spread Spectrum)
  • XOR of the signal with pseudo-random number
    (chipping sequence)
  • generate a signal with a wider range of
    frequency spread spectrum

27
Radio Technology
  • Spread Spectrum Technologies
  • Frequency Hopping The sender keeps changing the
    carrier wave frequency at which its sending its
    data. Receiver must be in synch with transmitter,
    and know the ordering of frequencies.
  • Direct-Sequence The receiver listens to a set of
    frequencies at the same time. The subset of
    frequencies that actually contain data from the
    sender is determined by spreading code, which
    both the sender and receiver must know. This
    subset of frequencies changes during
    transmission.
  • Non-Spread Spectrum requires licensing

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Wireless Standards
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Distance vs. Data Rate
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Bluetooth
  • Goals
  • Ad-hoc wireless connectivity for everything!
  • Original goal
  • Low-cost replacement for annoying wire between
    cellphone and headset
  • Result Two modes of operation
  • Point to point (serial wire replacement)
  • Point to multipoint (ad-hoc networking)

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Bluetooth devices
  • Cellphones
  • Headsets
  • PDAs
  • Laptops
  • Two-way pagers
  • Pads, tabs, etc

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Bluetooth design Specs
  • Started with Ericsson's Bluetooth Project in 1994
    !
  • Named after Danish king Herald Blatand (AD
    940-981) who was fond of blueberries
  • Radio-frequency communication between cell phones
    over short distances
  • Intel, IBM, Nokia, Toshiba, and Ericsson formed
    Bluetooth SIG in May 1998
  • Version 1.0A of the specification came out in
    late 1999.
  • IEEE 802.15.1 approved in early 2002 is based on
    Bluetooth
  • Key Features
  • Lower Power 10 µA in standby, 50 mA while
    transmitting
  • Cheap 5 per device
  • Small 9 mm2 single chips

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Bluetooth design Specs
  • Frequency Range 2402 - 2480 MHz (total 79 MHz
    band) 23 MHz in some countries, e.g., Spain
  • Data Rate1 Mbps (Nominal) 720 kbps (User)
  • Channel Bandwidth1 MHz
  • Range Up to 10 m can be extended further
  • RF hopping 1600 times/s gt 625 µs/hop
  • Security Challenge/Response Authentication. 128b
    Encryption
  • TX Output Power
  • Class 1 20 dBm Max. (0.1W) 100m
  • Class 2 4 dBm (2.5 mW)
  • Class 3 0 dBm (1mW) 10m

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Piconet
  • Piconet is formed by a master and many slaves
  • Up to 7 active slaves. Slaves can only transmit
    when requested by master
  • Up to 255 Parked slaves
  • Active slaves are polled by master for
    transmission
  • Each station gets a 8-bit parked address gt 255
    parked slaves/piconet
  • The parked station can join in 2ms.
  • Other stations can join in more time.
  • A device can participate in multiple piconets gt
    complex schedule

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Bluetooth Operational States
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Bluetooth Operational States (Cont)
  • Standby Initial state
  • Inquiry Master sends an inquiry packet. Slaves
    scan for inquiries and respond with their address
    and clock after a random delay (CSMA/CA)
  • Page Master in page state invites devices to
    join the piconet. Page message is sent in 3
    consecutive slots (3 frequencies). Slave enters
    page response state and sends page response
    including its device access code.
  • Master informs slave about its clock and address
    so that slave can participate in piconet. Slave
    computes the clock offset.
  • Connected A short 3-bit logical address is
    assigned
  • Transmit

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Bluetooth Packet Format
  • Packets can be up to five slots long. 2745 bits.
  • Access codes
  • Channel access code identifies the piconet
  • Device access code for paging requests and
    response
  • Inquiry access code to discover units
  • Header member address (3b), type code (4b), flow
    control, ack/nack (1b), sequence number, and
    header error check (8b) 8b Header is encoded
    using 1/3 rate FEC resulting in 54b
  • Synchronous traffic has periodic reserved slots.
  • Other slots can be allocated for asynchronous
    traffic
  • 54b 0-2754b

72b
Access Code Baseband/link Control Header Data Payload
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Bluetooth Energy Management
  • Three inactive states
  • Hold No ACL. SCO (Sync data) continues. Node can
    do something else scan, page, inquire
  • Sniff Low-power mode. Slave listens only after
    fixed sniff intervals.
  • Park Very Low-power mode. Gives up its 3-bit
    active member address and gets an 8-bit parked
    member address.
  • Packets for parked stations are broadcast to
    3-bit zero address.

Sniff
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Bluetooth Protocol Stack
  • RF Frequency hopping GFSK modulation
  • Baseband Frequency hop selection, connection,
    MAC

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Baseband Layer
  • Each device has a 48-bit IEEE MAC address 3
    parts
  • Lower address part (LAP) 24 bits
  • Upper address part (UAP) 8 bits
  • Non-significant address part (NAP) - 16 bits
  • UAPNAP Organizationally Unique Identifier
    (OUI) from IEEE
  • LAP is used in identifying the piconet and other
    operations
  • Clock runs at 3200 cycles/sec or 312.5 µs (twice
    the hop rate)

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Bluetooth Protocol Stack
  • Logical Link Control and Adaptation Protocol
    (L2CAP)
  • Protocol multiplexing
  • Segmentation and reassembly
  • Controls peak bandwidth, latency, and delay
    variation
  • Host Controller Interface
  • RFCOMM Layer
  • Presents a virtual serial port
  • Sets up a connection to another RFCOMM
  • Service Discovery Protocol (SDP) Each device has
    one SDP which acts as a server and client for
    service discovery messages
  • IrDA Interoperability protocols Allow existing
    IrDA applications to work w/o changes

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Bluetooth Protocol Stack
  • IrDA object Exchange (IrOBEX) and Infrared Mobile
    Communication (IrMC) for synchronization
  • Audio is carried over 64 kbps over SCO links over
    baseband
  • Telephony control specification binary (TCS-BIN)
    implements call control including group
    management (multiple extensions, call forwarding,
    and group calls)
  • Application Profiles Set of algorithms, options,
    and parameters. Standard profiles Headset,
    Cordless telephony, Intercom, LAN, Fax, Serial
    line (RS232 and USB).

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802.11 LAN Architectures
  • Distributed wireless Networks also called Ad-hoc
    networks
  • Centralized wireless Networks also called last
    hop networks. They are extension to wired
    networks.

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Wireless LAN Architecture
Ad Hoc
Laptop
Laptop
Server
DS
Pager
Laptop
PDA
Laptop
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Access Point Functions
  • Access point has three components
  • Wireless LAN interface to communicate with nodes
    in its service area
  • Wireline interface card to connect to the
    backbone network
  • MAC layer bridge to filter traffic between
    sub-networks. This function is essential to use
    the radio links efficiently

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Performance Metrics
  • Delay ave time on the MAC queue
  • Throughput fraction used for data transmission.
  • Fairness Not preference any node
  • Stability handle instantaneous loads greater
    than its max. capacity.
  • Robust against channel fading
  • Power consumption or power saving
  • Support for multimedia

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Wireless LAN Architecture, Cont
Logical Link Control Layer
MAC Layer Consist of two sub layer, physical
Layer and physical convergence layer
  • Physical convergence layer, shields LLC from the
    specifics of the physical medium. Together with
    LLC it constitutes equivalent of Link Layer of OSI

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802.11 Features
  • Power management NICs to switch to lower-power
    standby modes periodically when not transmitting,
    reducing the drain on the battery. Put to sleep,
    etc.
  • Bandwidth To compress data
  • Security
  • Addressing destination address does not always
    correspond to location.

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Power Management
  • Battery life of mobile computers/PDAs are very
    short. Need to save
  • The additional usage for wireless should be
    minimal
  • Wireless stations have three states
  • Sleep
  • Awake
  • Transmit

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Power Management, Cont
  • AP knows the power management of each node
  • AP buffers packets to the sleeping nodes
  • AP send Traffic Delivery Information Message
    (TDIM) that contains the list of nodes that will
    receive data in that frame, how much data and
    when?
  • The node is awake only when it is sending data,
    receiving data or listening to TDIM.

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IEEE 802.11 Topology
  • Independent basic service set (IBSS) networks
    (Ad-hoc)
  • Basic service set (BSS), associated node with an
    AP
  • Extended service set (ESS) BSS networks
  • Distribution system (DS) as an element that
    interconnects BSSs within the ESS via APs.

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ESS topology
  • connectivity between multiple BSSs, They use a
    common DS

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802.11 Logical Architecture
  • PLCP Physical Layer Convergence Procedure
  • PMD Physical Medium Dependent
  • MAC provides asynchronous, connectionless service
  • Single MAC and one of multiple PHYs like DSSS,
    OFDM, IR
  • and FHSS.

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802.11 MAC Frame Format
Bytes

342346
32
6
Preamble PLCP header MPDU
6
2
6
6
4
2
2
6
Bytes
Encrypted to WEP
Bits
2
1
2
4
1
1
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802.11 MAC Frame Format
  • Address Fields contains
  • Source address
  • Destination address
  • AP address
  • Transmitting station address
  • DS Distribution System
  • User Data, up to 2304 bytes long

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Special Frames ACK, RTS, CTS
bytes
2
2
6
4
Frame Control
Duration
Receiver Address
CRC
  • Acknowledgement
  • Request To Send
  • Clear To Send

ACK
bytes
2
2
6
6
4
Frame Control
Duration
Receiver Address
Transmitter Address
CRC
RTS
bytes
2
2
6
4
Frame Control
Duration
Receiver Address
CRC
CTS
57
IEEE 802.11 LLC Layer
  • Provides three type of service for exchanging
    data between (mobile) devices connected to the
    same LAN
  • Acknowledged connectionless
  • Un-acknowledged connectionless, useful for
    broadcasting or multicasting.
  • Connection oriented
  • Higher layers expect error free transmission

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IEEE 802.11 LLC Layer, Cont..
  • Each SAP (Service Access Point) address is 7
    bits. One bit is added to it to indicate whether
    it is order or response.
  • Control has three values
  • Information, carry user data
  • Supervisory, for error control and flow control
  • Unnumbered, other type of control packet

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IEEE 802.11 LLC lt-gt MAC Primitives
  • Four types of primitives are exchanged between
    LLC and MAC Layer
  • Request order to perform a function
  • Confirm response to Request
  • Indication inform an event
  • Response inform completion of process began by
    Indication

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Reception of packets
  • AP Buffer traffic to sleeping nodes
  • Sleeping nodes wake up to listen to TIM (Traffic
    Indication Map) in the Beacon
  • AP send a DTIM (Delivery TIM) followed by the
    data for that station.
  • Beacon contains, time stamp, beacon interval,
    DTIM period, DTIM count, sync info, TIM broadcast
    indicator

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Frame type and subtypes
  • Three type of frames
  • Management
  • Control
  • Asynchronous data
  • Each type has subtypes
  • Control
  • RTS
  • CTS
  • ACK

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Frame type and subtypes, Cont..
  • Management
  • Association request/ response
  • Re-association request/ response transfer from
    AP to another.
  • Probe request/ response
  • privacy request/ response encrypting content
  • Authentication to establish identity
  • Beacon (Time stamp, beacon interval, channels
    sync info, etc.)

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Frame type and subtypes, Cont..
  • Management
  • TIM (Traffic Indication Map) indicates traffic to
    a dozing node
  • dissociation

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802.11 Management Operations
  • Scanning
  • Association/Reassociation
  • Time synchronization
  • Power management

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Scanning in 802.11
  • Goal find networks in the area
  • Passive scanning
  • Not require transmission
  • Move to each channel, and listen for Beacon
    frames
  • Active scanning
  • Require transmission
  • Move to each channel, and send Probe Request
    frames to solicit Probe Responses from a network

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Association in 802.11
1 Association request
2 Association response
AP
3 Data traffic
Client
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Reassociation in 802.11
1 Reassociation request
New AP
3 Reassociation response
5 Send buffered frames
2 verifypreviousassociation
Client
6 Data traffic
Old AP
4 send buffered frames
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Time Synchronization in 802.11
  • Timing synchronization function (TSF)
  • AP controls timing in infrastructure networks
  • All stations maintain a local timer
  • TSF keeps timer from all stations in sync
  • Periodic Beacons convey timing
  • Beacons are sent at well known intervals
  • Timestamp from Beacons used to calibrate local
    clocks
  • Local TSF timer mitigates loss of Beacons

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Authentication
  • Three levels of authentication
  • Open AP does not challenge the identity of the
    node.
  • Password upon association, the AP demands a
    password from the node.
  • Public Key Each node has a public key. Upon
    association, the AP sends an encrypted message
    using the nodes public key. The node needs to
    respond correctly using it private key.

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02.11 Activities IEEE
  • 802.11c Bridge Operation (Completed. Added to
    IEEE 802.1D)
  • 802.11d Global Harmonization (PHYs for other
    countries. Published as IEEE Std 802.11d-2001)
  • 802.11e Quality of Service. IEEE Std
    802.11e-2005
  • 802.11f Inter-Access Point Protocol (Published
    as IEEE Std Std 802.11F-2003)
  • 802.11h Dynamic Frequency Selection and transmit
    power control to satisfy 5GHz band operation in
    Europe. Published as IEEE Std 802.11h-2003
  • 802.11i MAC Enhancements for Enhanced Security.
    Published as IEEE Std 802.11i-2004
  • 802.11j 4.9-5 GHz operation in Japan. IEEE Std
    802.11j-2004
  • 802.11k Radio Resource Measurement interface to
    higher layers. Active.

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02.11 Activities IEEE
  • 802.11m Maintenance. Correct editorial and
    technical issues in 802.11a/b/d/g/h. Active.
  • 802.11n Enhancements for higher throughput (100
    Mbps). Active.
  • 802.11p Inter-vehicle and vehicle-road side
    communication at 5.8GHz. Active.
  • 802.11r Fast Roaming. Started July 2003.
    Active.
  • 802.11s ESS Mesh Networks. Active.
  • 802.11T Wireless Performance Metrics. Active.
  • 802.11u Inter-working with External Networks.
    Active.
  • 802.11v Wireless Network Management enhancements
    for interface to upper layers. Extension to
    80211.k. Active.
  • Study Group ADS Management frame security.
    Active
  • Standing Committee Wireless Next Generation WNG
    Globalization jointly w ETSI-BRAN and MMAC.
    Active.

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Wireless MAC issues
  • Half duplex operations difficult to receive data
    while sending
  • Time varying channel Multipath propagation,
    fading
  • Burst Channel error BER is as high as 10-3. We
    need a better strategy to overcome noises.
  • Location dependant carrier sensing signal decays
    with path length.
  • Hidden nodes
  • Exposed nodes
  • Capture when a receiver can cleanly receive data
    from two sources simultaneously, the farther one
    sounds a noise.

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IEEE 802.11 Wireless MAC
  • Distributed and centralized MAC components
  • Distributed Coordination Function (DCF)
  • Point Coordination Function (PCF)
  • DCF suitable for multi-hop and ad hoc networking
  • DCF is a Carrier Sense Multiple Access/Collision
    Avoidance (CSMA/CA) protocol

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Hidden Terminal Problem
  • Node B can communicate with A and C both
  • A and C cannot hear each other
  • When A transmits to B, C cannot detect the
    transmission using the carrier sense mechanism
  • If C transmits, collision will occur at node B

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MACA Solution for Hidden Terminal Problem
  • When node A wants to send a packet to node B,
    node A first sends a Request-to-Send (RTS) to A
  • On receiving RTS, node A responds by sending
    Clear-to-Send (CTS), provided node A is able to
    receive the packet
  • When a node (such as C) overhears a CTS, it keeps
    quiet for the duration of the transfer
  • Transfer duration is included in RTS and CTS both

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IEEE 802.11
RTS Request-to-Send
RTS
C
F
A
B
E
D
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IEEE 802.11
RTS Request-to-Send
RTS
C
F
A
B
E
D
NAV 10
NAV remaining duration to keep quiet
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IEEE 802.11
CTS Clear-to-Send
CTS
C
F
A
B
E
D
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IEEE 802.11
  • DATA packet follows CTS. Successful data
    reception acknowledged using ACK.

CTS Clear-to-Send
CTS
C
F
A
B
E
D
NAV 8
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IEEE 802.11
DATA
C
F
A
B
E
D
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IEEE 802.11
Reserved area
ACK
C
F
A
B
E
D
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IEEE 802.11
DATA
C
F
A
B
E
D
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IEEE 802.11
ACK
C
F
A
B
E
D
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CSMA/CA
  • Carrier sense in 802.11
  • Physical carrier sense
  • Virtual carrier sense using Network Allocation
    Vector (NAV)
  • NAV is updated based on overheard
    RTS/CTS/DATA/ACK packets, each of which specified
    duration of a pending transmission
  • Collision avoidance
  • Nodes stay silent when carrier sensed
    (physical/virtual)
  • Backoff intervals used to reduce collision
    probability

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Backoff Interval
  • When transmitting a packet, choose a backoff
    interval in the range 0,cw
  • cw is contention window
  • Count down the backoff interval when medium is
    idle
  • Count-down is suspended if medium becomes busy
  • When backoff interval reaches 0, transmit RTS

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Computer Network
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DCF Example
B1 and B2 are backoff intervals at nodes 1 and 2
cw 31
Univ. of Tehran
Computer Network
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Backoff Interval
  • The time spent counting down backoff intervals is
    a part of MAC overhead
  • Choosing a large cw leads to large backoff
    intervals and can result in larger overhead
  • Choosing a small cw leads to a larger number of
    collisions (when two nodes count down to 0
    simultaneously)

Univ. of Tehran
Computer Network
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Binary Exponential Backoff in DCF
  • When a node fails to receive CTS in response to
    its RTS, it increases the contention window
  • cw is doubled (up to an upper bound)
  • When a node successfully completes a data
    transfer, it restores cw to Cwmin
  • cw follows a sawtooth curve
  • 802.11 has large room for improvement

Random backoff
Data Transmission/ACK
RTS/CTS
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Computer Network
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Inter Frame Spacing
  • SIFS Short inter frame space dependent on PHY
  • PIFS point coordination function (PCF) inter
    frame space SIFS slot time
  • DIFS distributed coordination function (DCF)
    inter frame space PIFS slot time
  • The back-off timer is expressed in terms of
    number of time slots.

Univ. of Tehran
Computer Network
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802.11 Frame Priorities
  • Short interframe space (SIFS)
  • For highest priority frames (e.g., RTS/CTS, ACK)
  • PCF interframe space (PIFS)
  • Used by PCF during contention free operation
  • DCF interframe space (DIFS)
  • Minimum medium idle time for contention-based
    services

DIFS
PIFS
contentwindow
Frame transmission
Busy
SIFS
Time
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Computer Network
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SIFS/DIFS
  • SIFS makes RTS/CTS/Data/ACK atomic
  • Example Slot Time 1, CW 5, DIFS3, PIFS2,
    SIFS1,

Univ. of Tehran
Computer Network
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Priorities in 802.11
  • CTS and ACK have priority over RTS
  • After channel becomes idle
  • If a node wants to send CTS/ACK, it transmits
    SIFS duration after channel goes idle
  • If a node wants to send RTS, it waits for DIFS gt
    SIFS

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Computer Network
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SIFS and DIFS
DATA1
ACK1
backoff
RTS
DIFS
SIFS
SIFS
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Computer Network
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Energy Conservation
  • Since many mobile hosts are operated by
    batteries, MAC protocols which conserve energy
    are of interest
  • Two approaches to reduce energy consumption
  • Power save Turn off wireless interface when
    desirable
  • Power control Reduce transmit power

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Computer Network
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Power Control with 802.11
  • Transmit RTS/CTS/DATA/ACK at least power level
    needed to communicate with the receiver
  • A/B do not receive RTS/CTS from C/D. Also do not
    sense Ds data transmission
  • Bs transmission to A at high power interferes
    with reception of ACK at C

B
C
D
A
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Computer Network
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Related Standards Activities
  • IEEE 802.11
  • http//grouper.ieee.org/groups/802/11/
  • Hiperlan/2
  • http//www.etsi.org/technicalactiv/hiperlan2.htm
  • BlueTooth
  • http//www.bluetooth.com
  • IETF manet (Mobile Ad-hoc Networks) working group
  • http//www.ietf.org/html.charters/manet-charter.ht
    ml

Univ. of Tehran
Computer Network
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