1.+Internet,+protocol,+access+networks,+Packet+switching+versus+circuit+switching,+network+structure,+etc.pdf

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Introduction to Computer Networks and the
Internet

Intro to Internet, protocol, network edge (hosts, access net,
physical media), packet/circuit switching, network core, Internet
structure

Chapter 1 sections 1.1, 1.2, 1.3

Introduction 1-1
What’s the Internet: “nuts and bolts” view
PC
▪ billions of connected mobile network
server computing devices:
wireless
laptop
hosts = end systems global ISP

smartphone running network apps
home
▪ communication links network
regional ISP
wireless fiber, copper, radio,
links satellite
wired
links transmission rate:
bandwidth

▪ packet switches: forward
router
packets (chunks of data) institutional
routers and switches network

Introduction 1-2
 “Fun” Internet-connected devices
Tweet-a-watt:
monitor energy use

bikes

Pacemaker & Monitor

Amazon Echo Web-enabled toaster +
IP picture frame
weather forecaster
Internet
refrigerator
Slingbox: remote cars
control cable TV
Security Camera AR devices
sensorized, scooters
bed
mattress

Gaming devices
Others?
Internet phones Fitbit
What’s the Internet? mobile network

nuts and bolts view global ISP

▪ Internet: “network of networks”
Interconnected ISPs home
network
▪ protocols control sending, receiving of regional ISP

messages
e.g., TCP, IP, HTTP, Skype, 802.11
▪ Internet standards
RFC: Request for comments
IETF: Internet Engineering Task Force
institutional
network
a service view
▪ infrastructure that provides services to applications:
Web, Video Streaming, VoIP, email, games, e-commerce, social nets, …
▪ provides programming interface to apps
hooks that allow sending and receiving app programs to “connect” to Internet
provides service options, analogous to postal service
Introduction 1-4
What’s a protocol?
▪ protocols define format, order of messages sent and received among
network entities, and actions taken on message transmission, receipt
human protocols: network protocols:
▪ “what’s the time?” ▪ machines rather than humans
▪ “I have a question” ▪ all communication activity in
▪ introductions Internet governed by protocols
… specific messages sent
… specific actions taken when
messages received, or other events

Hi TCP connection
request

Hi TCP connection
response
Got the
time? Get http://www.awl.com/kurose-ross
2:00 time
Q: other human protocols? Introduction 1-5
 A closer look at network structure:
▪ network edge: mobile network
hosts: clients and servers
servers often in data centers global ISP

▪ access networks, physical media:
wired, wireless communication links home
network
Q: How to connect end systems to edge regional ISP

routers?
▪ residential access networks
▪ institutional access networks (school, company)
▪ mobile access networks
▪ network core:
interconnected routers institutional
network of networks network

▪ keep in mind: bandwidth (bits per second) of access network?
▪ shared or dedicated? Introduction 1-6
Important Aspects of Computer Networks
Hardware: can be classified by:
Transmission Technology:
Broadcast Links:
Channel shared among all machines
e.g., Satellite, Multi-access Ethernet
Multicast Links:
Same as broadcast with access limitation to a subset of machines
Point-to-Point (Unicast) Links:
Connections between pairs of machines.
Scale:

Software

Introduction 1-7
 Access network: digital subscriber line (DSL)
Dual-Tone Multi-Frequency (DTMF) Network Interfact Device (NID)
Analog Signals (< 4 kHz) xDSL Transmission Unit (xTU)

central office telephone
Digital Signals
(> 4 kHz)
network
Plain Old Telephone Services (POTS)
Local Loop 0 < f < 4 kHz
(PCM Signalling)
DSL splitter
modem DSLAM

ISP
voice, data transmitted
at different frequencies over DSL access
dedicated line to central office multiplexer

▪ use existing telephone line to CO DSLAM (support up to 64 homes)
data over DSL phone line goes to Internet
voice over DSL phone line goes to telephone net Asymmetric Access
▪ Medium-speed upstream channel (4 < f < 50 kHz), Tx rate (typically < 1 Mbps)
▪ High-speed downstream channel (50 kHz < f < 1 MHz), Tx rate (typically < 10 Mbps)
Frequency Division Multiplexing (FDM)

Introduction 1-8
 Frequency V.S. Time Division Multiplexing
▪ Frequency Division Multiplexing

Each user is assigned a separate frequency.
Frequencies are spaced out in order to avoid interference.
▪ Time Division Multiplexing

Time is subdivided into slots of fixed size.
Each user is allocated a specific time slot.
Information only transmitted during allocated slot over the same frequency.
Access network: DSL – Cont’d.

Introduction 1-10
 Access network: DSL – Cont’d.
Plot of BW V.S. distance over Cat-3 UTP for DSL

BUSINESS MEETS TECHNOLOGY
Objectives:
Work over Cat-3 twister pair local loops.
Not affect existing telephones / fax machines.
Be faster than 56 kbps.
Always on with just monthly charge (no charge per minute).
Possible Solution:
Build several mini end offices in the neighborhoods (expensive)
Introduction 1-11
ANY ALTERNATIVE?
 Access network: DSL – Cont’d.
More Efficient Alternative Solution
Discrete Multi-Tone (DMT).
Available local loop spectrum (i.e. 1.1 MHz) divided into 256 independent channels:
Each channel is 4.3125 kHz wide.

Channel Usage
0 POTS
1 Unused
2 Unused
3 Unused
4 Unused
5 Unused
6 to 250 1 channel for upstream control
1 channel for downstream control.
25 channels upstream.
218 channels downstream.
Introduction 1-12
Access network: DSL – Cont’d.
DMT Channel Allocation

Introduction 1-13
 Metropolitan
Access network: cable network Area
Network
cable headend

…
broadcasts
TV channels
cable splitter
modem
distribution network of coaxial
cables and amplifiers

C
O
V V V V V V N
I
D
I
D
I
D
I
D
I
D
I
D
D
A
D
A
T
R
FDM
E E E E E E T T O
O O O O O O A A L

1 2 3 4 5 6 7 8 9

Channels
Hybrid Fiber Coax (HFC):
Fiber optics connect cable headend to neighborhood-level junctions.
Traditional coaxial cable is used to read individual houses.
Requires special cable modems.
Introduction 1-14
 Access network: cable network
cable headend

… cable modem
termination system
cable splitter turns analog signal
modem CMTS
sent from cable
modems into digital
data, TV transmitted at different format
frequencies over shared cable ISP
distribution network

▪ HFC: hybrid fiber coax
Cable modems divide the HFC network into two asymmetric channels
up to 30Mbps downstream transmission rate,
2 Mbps upstream transmission rate

▪ network of cable, fiber attaches homes to ISP router
homes share access network to cable headend
unlike DSL, which has dedicated access to central office Introduction 1-15
 Local
Access network: home network Area
Network
wireless
devices

to/from headend or
central office
often combined
in single box

cable or DSL modem

wireless access router, firewall, NAT
point (54 Mbps)
wired Ethernet (1 Gbps)

Introduction 1-16
Enterprise access networks (Ethernet)
Local Area Network

institutional link to
ISP (Internet)
institutional router

Ethernet institutional mail,
switch web servers

▪ typically used in companies, universities, etc.
▪ 10 Mbps, 100Mbps, 1Gbps, 10Gbps transmission rates
▪ today, end systems typically connect into Ethernet switch

Introduction 1-17
Wireless access networks
▪ shared wireless access network connects end system to router
via base station aka “access point”

wireless LANs: wide-area wireless access
▪ within building (100 ft.) ▪ provided by telco (cellular)
▪ 802.11b/g/n/ac/ax (WiFi): 11 operator, 10’s km
M/54 M/450 M/6.9 G/9.6 G ▪ between 1 and 10 Mbps
(bps) transmission rate ▪ 3G, 4G: LTE, 5G and Beyond

to Internet
to Internet

Introduction 1-18
Physical media
▪ bit: atomic entity propagates
between Tx/Rx pairs
▪ physical link: what lies Twisted Pair (TP)
between transmitter & ▪ two insulated copper wires
receiver Category 5: 100 Mbps, 1 Gbps
▪ guided media: Ethernet
Category 6: 10Gbps
signals propagate in solid
media: copper, fiber, coax Achievable rates depend on:
Wire’s thickness.
▪ unguided media:
Tx/Rx distance.
signals propagate freely,
▪ Unshielded TP (UTP):
e.g., radio
Used for indoor LANs and
residential access nets.
Introduction 1-19
Physical media: Coaxial Cable
▪ Common in cable TV systems.
▪ Two concentric copper conductors with special shielding and insulation.
▪ Bidirectional
▪ Can achieve high bit rates.
▪ Can be used as guided shared medium:
▪ Multiple end systems directly connect to cable.
▪ Each end system receives what is sent by other end systems.
▪ Broadband:
Multiple channels on cable
HFC

Introduction 1-20
Physical media: Fiber Optic Cables

Introduction 1-21
Physical media: radio
radio link types:
▪ signal carried in ▪ terrestrial microwave
electromagnetic spectrum
e.g. up to 45 Mbps channels
▪ no physical “wire”
▪ LAN (e.g., WiFi)
▪ bidirectional 54 Mbps
▪ propagation environment ▪ wide-area (e.g., cellular)
effects:
4G cellular: ~ 10 Mbps
reflection
▪ satellite
obstruction by objects Kbps to 45Mbps channel (or
interference multiple smaller channels)
270 msec end-end delay
geosynchronous versus low
altitude
Introduction 1-22
STARLINK Satellite Meshes

Introduction 1-23
Introduction 1-24
 The network core
▪ mesh of interconnected routers
▪ packet-switching: hosts break
application-layer messages into
packets
forward packets from one router to
the next, across links on path from
source to destination
▪ Each packet contains destination
Address (dst)
▪ Each packet treated independently
each packet transmitted at full link
capacity Introduction 1-25
 Host: sends packets of data
host sending function:
▪ takes application message two packets,
L bits each
▪ breaks into smaller chunks,
known as packets, of length L bits
2 1
▪ transmits packet into access
network at transmission rate R R: link transmission rate
host
link transmission rate, aka link
capacity, aka link bandwidth

packet time needed to L (bits)
transmission = transmit L-bit =
delay packet into link R (bits/sec)
Introduction 1-26
Packet-switching: store-and-forward

L bits
per packet

3 2 1
source destination
R bps R bps

▪ takes L/R seconds to transmit
one-hop numerical example:
(push out) L-bit packet into link
at R bps ▪ L = 7.5 Mbits
▪ R = 1.5 Mbps
▪ store and forward: entire packet
must arrive at router before it ▪ one-hop transmission
delay = 5 sec
can be transmitted on next link
▪ end-end delay = 2L/R (assuming
zero propagation delay) more on delay shortly …
Introduction 1-27
 Packet Switching: queueing delay, loss
Sources of delays and losses:

Introduction 1-28
Packet Switching: queueing delays behaviour

Introduction 1-29
 Two key network-core functions
routing: determines source-
destination route taken by packets
▪ routing algorithms & protocols: forwarding: move packets from
▪ automatically build and maintain router’s input to appropriate
the forwarding tables router output

routing algorithm

local forwarding table
header value output link
0100 3 1
0101 2
0111 2 3 2
1001 1

destination address in arriving
packet’s header
Introduction 1-30
Alternative core: circuit switching
end-end resources allocated
to, reserved for “call”
between source & dest:
▪ in diagram, each link has four
circuits.
call gets 2nd circuit in top
link and 1st circuit in right
link.
▪ dedicated resources: no sharing
circuit-like (guaranteed)
performance
▪ circuit segment idle if not used
by call (no sharing)
▪ commonly used in traditional
telephone networks
Introduction 1-31
Circuit Switching: Example

Introduction 1-32
Packet Switching V.S. Circuit Switching
packet switching allows more users to use network!

example:
▪ 1 Mb/s link
▪ each user: N
users
100 kb/s when “active”
active 10% of time 1 Mbps link

▪ circuit-switching:
10 users
▪ packet switching: Q: how did we get value 0.0004?
with 35 users, probability >
10 active at same time is less Q: what happens if > 35 users ?
than.0004 *
* Check out the online interactive exercises for more examples: http://gaia.cs.umass.edu/kurose_ross/interactive/
Introduction 1-33
Packet switching versus circuit switching
is packet switching a “slam dunk winner?”
▪ great for bursty data
resource sharing
simpler, no call setup
▪ excessive congestion possible: packet delay and loss
protocols needed for reliable data transfer, congestion
control
▪ Q: How to provide circuit-like behavior?
bandwidth guarantees needed for audio/video apps
still an unsolved problem (chapter 7)

Q: human analogies of reserved resources (circuit switching)
versus on-demand allocation (packet-switching)?
Introduction 1-34
Internet structure: network of networks

▪ End systems connect to Internet via access ISPs (Internet
Service Providers)
residential, company and university ISPs
▪ Access ISPs in turn must be interconnected.
so that any two hosts can send packets to each other
▪ Resulting network of networks is very complex
evolution was driven by economics and national policies
▪ Let’s take a stepwise approach to describe current Internet
structure

Introduction 1-35
Internet structure: network of networks
Question: given millions of access ISPs, how to connect them
together?
access access
net net
access
net
access
access net
net
access
access net
net

access access
net net

access
net
access
net

access
net
access
net
access access
net access net
net

Introduction 1-36
Internet structure: network of networks
Option: connect each access ISP to every other access ISP?

access access
net net
access
net
access
access net
net
access
access net
net

connecting each access ISP
access
to each other directly doesn’t access
net
scale: O(N2) connections. net

access
net
access
net

access
net
access
net
access access
net access net
net

Introduction 1-37
Internet structure: network of networks
Option: connect each access ISP to one global transit ISP?
Customer and provider ISPs have economic agreement.
access access
net net
access
net
access
access net
net
access
access net
net

global
access
net
ISP access
net

access
net
access
net

access
net
access
net
access access
net access net
net

Introduction 1-38
Internet structure: network of networks
But if one global ISP is viable business, there will be competitors
….
access access
net net
access
net
access
access net
net
access
access net
net
ISP A

access
net ISP B access
net

access
net
ISP C
access
net

access
net
access
net
access access
net access net
net

Introduction 1-39
Internet structure: network of networks
But if one global ISP is viable business, there will be competitors
…. which must be interconnected
access access
Internet exchange point
net net
access
net
access
access net
net

access
IXP access
net
net
ISP A

access
net
IXP ISP B access
net

access
net
ISP C
access
net

access peering link
net
access
net
access access
net access net
net

Introduction 1-40
Internet structure: network of networks
… and regional networks may arise to connect access nets to
ISPs
access access
net net
access
net
access
access net
net

access
IXP access
net
net
ISP A

access
net
IXP ISP B access
net

access
net
ISP C
access
net

access
net regional net
access
net
access access
net access net
net

Introduction 1-41
Internet structure: network of networks
… and content provider networks (e.g., Google, Microsoft,
Akamai) may run their own network, to bring services, content
close to end users
access access
net net
access
net
access
access net
net

access
IXP access
net
net
ISP A
Content provider network
access
net
IXP ISP B access
net

access
net
ISP C
access
net

access
net regional net
access
net
access access
net access net
net

Introduction 1-42
Internet structure: network of networks

Tier 1 ISP Tier 1 ISP Google

IXP IXP IXP

Regional ISP Regional ISP

access access access access access access access access
ISP ISP ISP ISP ISP ISP ISP ISP

▪ at center: small # of well-connected large networks
“tier-1” commercial ISPs (e.g., Level 3, Sprint, AT&T, NTT), national &
international coverage
content provider network (e.g., Google): private network that connects
it data centers to Internet, often bypassing tier-1, regional ISPs Introduction 1-43