Digital Cellular Network Technology
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Transcript of Digital Cellular Network Technology
‘Digital Cellular Network Technologies’
An Overview
National-Level Faculty Development Workshop
“Challenges for Research in Wireless Communication Technologies”
May 21-23, 2012
Chitkara University, Punjab
Presented by
Prof. T. L. Singal
1
Evolution of Cellular Generations – A Recap
2
Cellular Network Generations
• 1G: First Generation Analog Cellular System - Analog voice
• 2G: First Digital Cellular System
- Digital voice and messaging
• 2.5 G: Digital Cellular System
- Increase in digital data rates
• 3G: Digital Cellular System with increase in functionality - Broadband data and Voice over IP
• 4G: Future re-architecting of digital cellular infrastructure - Increased data throughput 3
Examples of 1G and 2G
• First Generation Cellular Networks (1G)
– Analog systems based on FDMA (e.g. AMPS, NMT, UK-TACS)
• Second Generation Cellular Networks (2G)
– Digital systems based on TDMA and CDMA (e.g. GSM, TIA/EIA-136, IS-95)
• Second Generation+ Cellular Networks (2.5G)
– Digital systems based on TDMA and CDMA with higher data rate capabilities (e.g. GPRS, cdma2000)
4
Advantages/Disadvantages -
1G and 2G Networks
• First Generation Cellular Networks (1G)
– Spotty coverage
• Second Generation Wireless (2G)
– Improved voice quality
– Limited low-speed, circuit-switched data capabilities
• Second Generation Wireless + (2.5G)
– Introduction of packet data
– Higher data rates (up to 144 kbps) 5
3G and 4G
• Third Generation Cellular Networks (3G)
– Digital systems based on TDMA (GSM) and CDMA with data rate capability upto 2 Mbps (e.g. WCDMA/UMTS, cdma2000, UWC-136)
• Fourth Generation Cellular Networks (4G)
– Digital systems based on OFDMA and MC-CDMA with higher data rate capability for advanced multimedia applications.
6
Evolution of Cellular Networks
Fourth Generation
7
Key Parameters
8
Paradigm shift - 1G towards 4G
Fourth Generation
9
Comparison of 1G to 4G Systems
OFDMA,
MC-CDMA
Generation 1G 2G 3G 4G
10
GSM and CDMA
11
Multiple Access
Technologies
12
GSM - FDMA and TDMA
1 2 3 4 5 6 ARFCN
Frequency
Amplitude
Time
0
1
2
3
4
5
6
7
time slot number
13
GSM carriers are spaced 200
KHz apart.
In the BTS downlink signal,
different timeslots belong to
different users - a mobile
listens only to its recurring
timeslots.
The mobile on its uplink
transmits only during its
assigned timeslots.
Structure of a GSM Signal
14
GSM Network Areas
Cells
Location
Areas
MSC/VLR
service areas
PLMN service area
15
GSM Cell Plan
16
GSM Network Architecture
NMC
Interface to other
networks
MS
M
S
BTS
BTS
BTS
BSS
BSS MSC MSC
MSC MSC
VLR
VLR
HLR
EIR
AuC
OMC OMC BSC
BTS
BTS
BTS
BSC
17
A Typical GSM System
18
Advantages/Disadvantages
- GSM Network • Advantages
– Can provide roaming services
– Reduces probability of total corruption of speech
– Offers standard protocols between components
• Disadvantages
– Limited data rate capability
– Macrocells affected by multipath signal loss
– Low Capacity 19
GSM Networks Future Trends
GSM
Data
HSCSD
GPRS
EDGE
EGPRS
WCDMA
1999 2000 2002
WCDMA
Phase I
Evolution
9.6 kbps
9.6 - 28.8 kbps
9 - 53.6 kbps
<470 kbps
144 - 384 kbps
384 - 2048 kbps
2001 2003-2005
20
What is CDMA?
Code Division Multiple Access
CDMA is a spread spectrum system and is directly related to
the number of users accessing the system.
CDMA system allow one-cell frequency reuse and all users
use the entire carrier, all the time. Each user is distinguished
by a Direct Sequence Code during a call.
21
CDMA: Using A New Dimension
22
CDMA is a Spread- Spectrum System
23
CDMA Cell Plan
1
1
1
1
1
1
1
1
1
24
CDMA Network Architecture
Interface to other
networks
MS
MS
BTS
BTS
BTS
BS
BS MSC MSC
MSC MSC
VLR
VLR
HLR
EIR
AuC
OS
BSC
BTS
BTS
BTS
BSC
25
• Easy frequency planning (Frequency reuse of one)
• Greater coverage with fewer cells
• High capacity without hard blocking limits
• Excellent call quality (supports soft handoff)
• Inherent privacy due to unique user codes
• Lower power transmission
• Longer battery life
• Tight power control
• Technology platform extendable to new services
• Providing reliable transport mechanism for data communications, such as facsimile and internet traffic
CDMA - Advantages
26
CDMA - Advantages contd…
Dramatically improving the telephone traffic capacity.
Significantly improving the voice quality and eliminating
the audible effects of multipath fading.
Reducing the incidence of dropped calls due to handoff
failures.
Reducing the number of sites needed to support any
given amount of traffic.
Simplifying site selection, thus reducing deployment and
operating costs because fewer cell sites are needed.
Reducing average transmitted power, thereby reducing
interference. 27
Capacity Comparisons
– GSM and CDMA
GSM Capacity limit is fixed
at 8 x number of ARFCNs
per cell
CDMA Capacity limit is
„soft‟, Increases with
decrease in quality.
Typically 4-5 times that of
a GSM system. 28
GSM
Architecture
29
30
31
2G+ Cellular Network
32
3G Market Drivers
33
How Do Operators Get to 3G?
34
3G air interface technologies
WCDMA/UMTS cdma2000 UWC-136
CDMA-based CDMA-based TDMA-based
Direct sequence Multi-carrier --
Evolution of GSM Evolution of
IS-95
Evolution of
TDMA
Requires new
spectrum
Could be
deployed in
existing spectrum
Could be
deployed in
existing spectrum 35
GPRS Architecture
36
Example for packet
routing in GPRS
37
Example of GPRS Internet
Connection
38
The GSM Technology Path to 3G
39
3 Steps to 3G:
The GSM Network Transition
40
GSM Network
ANSI-136 Network
ANSI-136 GSM
IW MAP IW ANSI-41
EGPRS
UWC-136/EDGE
TCP/IP
Network
Mobility Gateway
Global TDMA Convergence
The CDMA Technology Path to 3G
42
3G Network Architecture
43
Advantages – The 3G Network
• Common worldwide spectrum
• Global seamless roaming
• Multimedia services on the mobile internet
• Flexible, spectrum-efficient network
• Enhanced security and performance
• Wireline services and quality levels
• Rapid introduction of new technology
44
Disadvantages – The 3G Network
• Insufficient bandwidth
• Service differentiation
• IP translators are the wrong application and
service model (e.g., WAP, imode, etc.)
• Wrong architectural model for IP data
45
KEY APPLICATIONS
• Current: ~10 kb/s, circuit/packet
– Fax
– Short-messaging
– Being evolved to ~50-100 kb/s peak rate
• Needed to make wireless data attractive:
– Web Browsing - downlink bandwidth hungry
– FTP or Emails with file attachment - both links
• 3G: “Multimedia,” mainly packet
– Wide-area, low mobility, 384 kb/s
– Wide-area, high mobility, 144 kb/s
– Indoor, 2 Mb/s
• Beyond 3G ?
Radio Technology Evolution
• High Speed Services
– Nominal Rates:
• At least 144 kbps macrocell
• At least 384 kbps outdoor pedestrian
• At least 2 Mbps indoor
• => 1-2 Mbps or higher in macrocell
– Support emerging IP-based services
• Real-time and non real-time
– Optimized for packet-switched operation
• Support appropriate QoS definitions
• Data and multimedia services
Technology Evolution to IMT-
2000 Radio Access
GSM
PDC
TDMA
(IS-136)
CDMA
(IS-95)
GSM+ GPRS
TDMA
IS-136+
CDMA 3G-1X
UWC-136 HS
(EDGE)
UMTS/
W-CDMA
EDGE/GPRS
cdma2000
IMT-2000
Systems
Existing
Spectrum New
Spectrum
?
?
Deployment Scenario
GPRS
backbone
SGSN GGSN
GGSN
BG
Public
Internet
Backbone
router
router server
router
SGSN
Edge
Edge
GPRS
backbone
GGSN
GGSN BG
SGSN
WCDMA
Inter- operator
GPRS
Wireless Data Terminals
Nokia 9110 Nokia
3G vision Sierra PCMCIA
CDPD Modem The new
Ericsson R380
phone, which
features wireless
data functions
Looking to the Future….
4G and Beyond
51
52
Transition from 3G to 4G ….
53
Positions and Challenges for 4G
• Wireless Data is king
– Direction: design for data and IP - not voice circuits
• Wide variety of wireless link technologies; 2G/3G,
wireless LAN, MANETs, PANs, wireless sensor networks;
new radio 4G technologies will emerge
– Direction: IP over every radio link
• Multitude of mobile devices; sensors, watches, pagers,
pocket PCs, etc.
– Direction: IP on every mobile device 54
Key Elements of 4G Vision
55
• Fully converged services
Personal communications, information systems, broadcast,
entertainment and a wider range of services available conveniently,
securely and in a manner reflecting the user’s personal preferences.
• Ubiquitous mobile access
The dominant mode of access will be mobile, accounting for fully
converged services, including mobile access to commercial and
retail services.
• Diverse user devices
The user will be served by a wide variety of low-cost mobile devices
to access content conveniently and seamlessly. Devices will interact
with users in a multi-sensory manner. 56
• Autonomous networks
4G systems will be highly autonomous adaptive networks capable of
self-management of their structure to meet users’ changing and
evolving demands, for both services and capacity. Efficient and cost-
effective use of the radio spectrum will be an essential element of their
operation.
• Software dependency
Intelligent Mobile Agents will exist throughout the networks and in
user devices, acting continually to simplify tasks and ensure
transparency to the user. These Mobile Agents will act at all levels,
from managing an individual user’s content preferences, to organizing
and reconfiguring major elements of networks.
57
Advantages - The 4G Network
• Improved Spectral Efficiency
• Improved quality of service
• Increased data throughput
• Broadcast and Cellular Network Convergence
• Adaptive and Reconfigurable Systems
• Advanced Antenna Technologies
• Creation of new business models for operators
58
4G Network Architecture
59
4G Network Scenario
60
4G Network Connectivity
61
Vision of Beyond 4G
62
Evolution from voice-only to
multimedia mobile services
63
Ultimate Goal – Maximum Data Rate
64
He executed international assignment as Senior Network Consultant with Flextronics International Inc. USA during 2000-02. He was associated with Nokia, AT&T, Cingular Wireless and Nortel Networks, for optimization of 2G/3G Cellular Networks in USA. Since 2003, he is in teaching profession in engineering colleges in India. He has number of technical research papers published in the IEEE Proceedings, Journals, and International/National Conferences. He has authored two text-books `Wireless Communications’ and `Analog & Digital Communications’, published by renowned publisher Tata McGraw-Hill.
T. L. Singal graduated from National Institute of
Technology, Kurukshetra in 1981 . He began his
illustrious career with Avionics Design Bureau at
HAL, Hyderabad and worked on design and
development of Air-Route Surveillance Radar
Communication System. Then he led R&D group in
a Telecom company and successfully developed
Multi-Access Wireless Communication Systems.
65
References
T L Singal, Wireless Communications,
ISBN: 978-0-07-068178-1,
Tata McGraw-Hill, First Edition, 2010.
www.mhhe.com/singal/wc
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