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Trends in Telecommunications Technology

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Title: Trends in Telecommunications Technology


1
Trends in Telecommunications Technology
  • Presentation by
  • Dale N. Hatfield
  • Adjunct Professor, University of Colorado at
    Boulder
  • at the
  • Institute for Regulatory Law and Economics (IRLE)
  • Aspen Colorado
  • May 21, 2006

2
Introduction
  • Purpose

To provide non-engineers with an overview of
major trends in telecommunications technology
3
Outline
  • Review of Basic Concepts
  • Answer Seven Questions About Trends
  • Analog versus Digital -- Why Digital?
  • Voice versus Data -- Whats the Difference?
  • Circuit Switching versus Packet Switching -- Why
    Packet Switching?
  • Narrowband versus Broadband -- Why Broadband?

4
Outline
  • Answer Seven Questions About Trends (Contd)
  • High Latency versus Low Latency -- Why Low
    Latency?
  • Intelligence Interior to the Network versus at
    the Edge of the Network -- Why at the Edge?
  • Wired versus Wireless -- Why Wireless?
  • The Network of the Future

5
The Digital Revolution
  • Analog Signal

Intensity
Time
6
The Digital Revolution
  • Digital Signal

Intensity
Time
0 1 0 0 0 1 0 1 1 0 0
7
The Digital Revolution
  • Analog to Digital and Digital to Analog Conversion

Sequence of Numbers (Transmitted as a Sequence of
Binary Numbers)
Analog Signal
Analog Signal
12.3 12.6 12.9 13.6 13.9 14.8 14.1
13.9
D/A
A/D
On and Off Pulses Representing Binary Numbers
8
Analog vs. Digital -- Why Digital?
  • Analog Amplification vs. Digital Regeneration

AMP
AMP
AMP
OUTPUT
INPUT
Analog Amplification Noise Accumulates
Repeater
Repeater
Repeater
INPUT
Digital Regeneration Perfect Signal is
Regenerated
9
Analog vs. Digital Why Digital?
  • Why Digital?
  • Digital Regeneration

10
Analog vs. Digital -- Why Digital?
  • Advantages
  • Signal Regeneration
  • Ease of Multiplexing
  • Ease of Encryption
  • Ease of Signaling
  • Use of Modern Technology (Moores Law)
  • Performance Monitorability
  • Operability at Low Signal/Noise or
    Signal/Interference

11
Analog vs. Digital -- Why Digital?
  • Advantages (Contd)
  • Integration of Switching and Transmission
  • Accommodation of Other Services
  • Disadvantages
  • Larger Bandwidth Requirements
  • Critical Timing
  • Need for Analog to Digital Converters

Source Bellamy, Digital Telephony
12
Voice vs. Data-- Whats the Difference?
  • Voice
  • Information rate constant
  • Intolerant of delays and variations in delay
  • Tolerant of noise/distortion
  • Symmetrical
  • Data
  • Information rate bursty/fractal
  • Tolerant of delay
  • Intolerant of noise/interference
  • Often asymmetrical

13
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Types of Switching

Circuit Switching The practice of establishing
an end-to-end connection between users of a
network. The associated facilities are dedicated
to the particular connection for the duration of
the call. Message Switching The practice of
transporting complete messages from a source to a
destination in non-real time and without
interaction between the source and destination,
usually in a store-and-forward fashion Packet
Switching The practice of transporting messages
through a network, in which long messages are
subdivided into short packets. The packets are
then transmitted as in message switching (i.e, in
a store-and-forward fashion)
Source
14
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Traditional Circuit Switched Connection

IXC POP
IXC POP
Key LECLocal Exchange Carrier IXCInterexchange
Carrier CO Central Office POPPoint of Presence
LEC CO
LEC CO
15
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Traditional Packet Switched Network

PS
Host Computer
PS
Dumb Terminal
PS
PS
"Dumb" Terminal
A
M
PS
A
M
PS
Addressed Packets
Dumb Terminal
(e.g. collection of
characters)
PS Packet Switch Functions Error Control,
Routing, Flow Control
16
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Because of the differences between voice and
    data, in the past
  • Circuit switching and time division multiplexing
    were used in the public switched telephone
    network (PSTN)
  • Packet switching and statistical multiplexing was
    used in public (and private) switched data
    networks

17
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Circuit Switching and Time Division Multiplexing
  • Advantages
  • No transmission delay
  • Disadvantages
  • Only fixed increments of bandwidth provided
  • Inefficient channel utilization for bursty
    traffic
  • High call setup overhead

18
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Packet Switching and Statistical Multiplexing
  • Advantages
  • User does not consume network resources when no
    information is being sent
  • Bandwidth on demand
  • Efficient utilization of transmission lines and
    ports
  • Efficiently handle asymmetric traffic
  • Offers always on connectivity

19
Circuit Switching vs. Packet Switching -- Why
Packet Switching?
  • Packet Switching and Statistical Multiplexing
  • Advantages
  • Provides the ability to handle different types of
    signals -- voice, data, image, and video on
    common transmission and switching platforms
  • Disadvantages
  • Delay (higher latency)
  • Per packet overhead

20
Narrowband vs. Broadband-- Why Broadband?
  • In simple terms, bandwidth is just a measure of
    how fast information can be transmitted
  • The larger the bandwidth, the more information
    that can be transmitted in a given amount of time

21
Narrowband vs. Broadband-- Why Broadband?
  • In the digital world, bandwidth is measured in
    bits per second
  • Analogous measures vehicles per hour or gallons
    per minute

22
Narrowband vs. Broadband -- Why Broadband?
  • To over simplify
  • Voice requires only narrow bandwidths
    (narrowband)
  • Still images require wide bandwidths (wideband)
  • Video requires broad bandwidths (broadband)

For transmission of the image in a reasonable
amount of time
23
Narrowband vs. Broadband-- Why Broadband?
  • Illustration of the Importance of Bandwidth

Computer Monitor
24
High Latency vs. Low Latency-- Why Low Latency?
  • In simple terms, latency just refers to delay
  • Latency is the amount of time it takes
    information (e.g., a packet) to travel from
    source to destination
  • In combination, latency and bandwidth define the
    speed and capacity of a network
  • Low latency is critical in voice communications
    and certain real-time data communications
    applications

25
Intelligence Interior to the Network versus at
the Edge of the Network -- Why at the Edge?
  • Architecture of the Traditional Public Switched
    Telephone Network
  • Circuit switching
  • Dumb terminals with limited capabilities
  • Intelligence residing in switches, intelligent
    peripherals, service control points, etc.
    interior to the network
  • Services created inside the network

26
Intelligence Interior to the Network versus at
the Edge of the Network -- Why at the Edge?
  • Architecture of Networks Based Upon the Internet
    Protocol (IP)
  • Packet switching
  • Dumb network
  • Intelligent terminals (e.g., PCs) with a rich
    set of capabilities
  • Services created in terminals/servers at the edge
    of the network

27
Wired versus Wireless -- Why Wireless?
  • Motivation for Wireless
  • Increased mobility of the workforce and society
    more generally
  • Increased efficiency and convenience and safety
  • Potentially lower infrastructure costs for
    certain fixed applications more fungible
    investment
  • Other

28
Wired versus Wireless -- Why Wireless?
  • Evolution of Commercial Mobile Radio Services
  • First generation analog, circuit switched,
    narrowband
  • Second generation digital, circuit switched,
    narrowband
  • Third generation digital, packet oriented,
    wideband/broadband

29
The Network of the Future
  • Network Trends/Goals from a Technological
    Perspective
  • All applications -- voice, data, image, video,
    multimedia -- conveyed on an all digital,
    packet-switched, broadband, low latency network
    or platform
  • A network of networks platform that uses
    common, open, non-proprietary standards and
    protocols (e.g., the Internet Protocol -- IP)

30
The Network of the Future
  • Network Trends/Goals from a Technological
    Perspective (Contd)
  • Extension of this platform using wireless
    technology to allow users to communicate
    anyplace, anytime, in any mode or combination of
    modes.

31
The Network of the Future
  • Integrated Network with Integrated Access

Integrated End User Device (Voice, Data, Video,
Multimedia)
Customer Node
Network Node
IP Based Network
Access Network DSL, Cable Modem, Wireless
(Cellular, Wi-Fi, etc), Satellite, Other
Customer Premises
Access
Backbone
Local/Regional
32
Contact Information
Dale N. Hatfield Adjunct Professor Interdisciplin
ary Telecommunications Program University of
Colorado at Boulder Engineering Center -
ECOT-311 Campus Box 530 Boulder, CO
80309-0530 Main Tel 1 303-492-8916 Direct Dial
1 303-492-6648 Fax 1 303-492-1112 Email
dale.hatfield_at_ieee.org or hatfield_at_spot.colorado.e
du
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