Wireless Networking Additional Slides.ppt

Chapter 2
Basics of Wireless
Networks
These slides are based on the slides formatted by Dr Sunilkumar S. manvi and Dr Mahabaleshwar S. Kakkasageri,
the authors of the textbook: Wireless and Mobile Networks, concepts and protocols. See slide number one.

Learning objectives

To
understand wireless networks
 To know the access technologies
 To study problems such as interference, multi-path
propagation, path loss, battery life, etc.
 To illustrate issues like channel allocation, routing,
mobility, security, power management,
etc.

Wireless networks
Wired network
 Wire as communication
 High data rate
 No mobility
medium
Wireless network
 Radio waves and
 Less data rate
 Highly portable
 Mobility
air as a medium

Wireless networks (Contd..)
 Provide
Internet
inexpensive and rapid connection setup with
 Restricted by distance

Overlapping
radio cells to provide connectivity

Wireless network architecture
It consists of mobile hosts, fixed hosts, access stations (BS),
core network to support mobility and switching.

Wireless network architecture (Contd..)
Mobile host
 Laptop, mobile phone, PDA, notebook, etc. can
move from one place to another place while
maintaining connection with wireless network.
Fixed wireless host
 Cannot move but the medium is radio waves.
 Example: wireless web servers, printers, etc.
Access Network
 Consists of access stations (BS) which provide
services to hosts reachable from it.

Wireless network architecture (Contd..)
Core Network
 Consists of active components that perform
data switching between access stations (BS),
and provide location and mobility services.
 Facilitates communication from mobile host to
mobile host, mobile host
ﬁxed
to wired node, ﬁxed
host,
host
etc.
to wired node, host to mobile

Classification of wireless networks
 Wireless
 Wireless
 Wireless
 Wireless
 Wireless
body area networks
personal area networks
local area networks
metropolitan area networks
wide area networks such as
and
GSM or
CDMA cellular networks
 Satellite networks and
broadband
access networks

Classification of wireless
(Contd..)
networks

(Contd..)
Wireless Body Area Network (WBAN)
networks
 Max. signal range 2 meters
 Interconnecting respective devices within the surface of the body




(Contd..)
networks
Wireless Body Area Network (WBAN)

(Contd..)
networks
Wireless Personal Area Network (WPAN)
 Max. signal range of 10 meters

(Contd..)
Wireless Local Area Network (WLAN)
• Signal range is ≈100 meters.
• Also called the Wireless Fidelity (Wi-Fi or IEEE 802.11)

Recall: an example of wired LAN
Station
Work
Printer
Server
Laptop
Work
Station
Laptop
Laptop
Work
Station

An example of wireless LAN
A user is connected if
he/she is in the coverage
area of a cell
Each cell operates at a
different frequency
Work
Station
Work
Station
Work
Station
Work
Station
Work
Station
Printer
Server
Access
Point
Access
Point
Access
Point
Access
Point
Access
Point
Access
Point
Laptop Laptop Laptop
Laptop
Laptop
Work
Station

(Contd..)
Wireless Metropolitan Area Network (WMAN)
 Signal range of approximately 5 km to 20 km (recently up to 50
km)
 Often called Worldwide Interoperability for Microwave Access
(WiMAX or IEEE 802.16)
Wi-Fi users
may be
connected to
the WiMAX
network
WiMAX BS
Mobile devices
might have
built in WiMAX
adapter or may
be externally
plugged
WMAN might
be owned and
operated by
organizations
or public
institutions

(Contd..)
Wireless Wide Area Network (WWAN)
 Use network infrastructure of mobile operators.
 Cover wide area much wider than groups mentioned above.
 Use cellular network technologies such as WI-MAX, GSM, GPRS,
3G and others.

Wireless switching technology
Packet switching is the basic type of
technology
 Uses short bursts of information,
wireless switching
uses channels only
for short periods of time.
protocols.
 Standard routing

Recall: Packet switching
2nd
From W. Stallings, Wireless Communications and Networks, Edition

Recall: Packet switching (Contd..)
From W. Stallings, Wireless Communications and Networks, 2nd Edition

Wireless switching technology (Contd..)
- Packets are routed and pipelined using multiplexing
- Bandwidth is used only when data is transmitted

Wireless switching technology (Contd..)
Virtual circuit
 Switched virtual circuits (SVCs)
 Established dynamically on demand
 3 phases – circuit establishment,
termination
data transfer, circuit
 Permanent virtual
circuits
(PVCs)
transfer
 Only one mode i.e., data

Wireless communication
 Increased bit error rate
 Lower transmission power
 Scattering
 Reflection
 Diffraction
problems
 Multipath propagation
 Path loss

Wireless communication problems
Increased bit error rate
Wireless network media is more prone to
 obstacles between Tx and Rx
 Interference from neighbour nodes
One can observe
errors due to
 Frequent disconnections causing to data loss
 Annoying to voice and video clients

Wireless communication problems (Contd..)
Lower transmission power
 Mobile units powered by battery have scarce energy resources
 Limited transmission power to avoid interference
 Attenuation
Capture power at the receiver side is Pr = Pt / (4 πd / l)2
Where Pt is the transmitter power, d the distance between
and the receiver, and l is the wavelength of the signal.
Lp = (4 πd / l)2 is the path loss.
Scattering
the transmitter
 Occurs when signal pass through the object whose dimension is
smaller than the wavelength.
 Scattered waves are produced by rough surfaces, small objects,
irregularities in the channel. Need
reduce it.
proper deployment strategies to

(Contd..)
Reflection
 Occurs when electromagnetic wave strikes an object which has
very large dimension compared to the wave length. Ex: walls,
furniture,
buildings, etc.
Diffraction
 Occurs when radio path between Tx and Rx is obstructed by surfaces
that
will
have sharp irregularities (edges) causing secondary waves, which
be present in space and behind the obstacle.

(Contd..)
Multipath Propagation
 Caused by reflection and scattering
 Radio waves arrive at the Rx from different
delays
 Final signal is the summation of all signals
directions with varying
 Antenna diversity
methods
are used to overcome this problem

Wireless network reference model
 The
OSI
TCP/IP architecture is functionally equivalent to the
reference model.

Recall: TCP/IP Concepts
2nd
From W. Stallings, Wireless Communications and Networks, Edition

Protocol Data Units in the TCP/IP
Architecture
Examples:
TCP header includes destination port, sequence number, checksum
IP header includes destination host address (B in previous example)
Network header includes destination subnetwork address
From W. Stallings, Wireless Communications and Networks, 2nd Edition

(Contd..)
 Major similarities and differences between
TCP/IP and the OSI reference models are
 Both models have an application, a
transport, and a network/Internet layer
 The TCP/IP model does not have a
session layer
 Lower layers connects the upper layers
to the actual physical network

(Contd..)
 Application layer functions
 This is the layer where end user applications such as remote
login,
mail transfer, ﬁle transfer, network management, and web
browsers
run
 Transport layer functions
 Its job is to provide reliable communication from application to
application (end-to-end) regardless of
communication links
 It encapsulates
application layer data layer
the lower-layer protocols and
and deliver it to the network

Illustration of the transport service

(Contd..)
 Data link layer functions
 This includes the logical link control (LLC) sublayer and
MAC (media access control) sublayer.
the
 It does segmenting the bit stream into frames, error handling,
ﬂow control, and access control.
 MAC is
channel
responsible
and reliable
for accessing and sharing of the wireless
delivery by using acknowledgments.

Illustration of data link layer
Bridge
802.4 LLC P
802.4 LLC P
802
802.3 LLC P
LLC P
802.3 LLC P 8024 LLC P
802.3 LLC P 802
Computer A
P
LLC P
802.3 LLC P
802.3 LLC P
Computer B
P
LLC P
802.4 LLC P
802.4 LLC
P

(Contd..)
 Physical layer functions
 This layer transports encapsulated data from the data link
transmits it wirelessly to the distant network.
layer and
 The wireless features and functionality (modulation type, data rate,
and so on) take place at this layer.

Wireless Networking Additional Slides.ppt

More Related Content

Similar to Wireless Networking Additional Slides.ppt (20)

Recently uploaded (20)

Wireless Networking Additional Slides.ppt