Networks

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Networks

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Title: Networks

1
Networks

Goal Communication between computers
Eventual Goal treat collection of computers as
if one big computer, distributed resource sharing
Theme Different computers must agree on many
things
Overriding importance of standards and protocols
Error tolerance critical as well

2
Networking

Issues
direct (point-to-point) vs. indirect (multi-hop)
topology (e.g., bus, ring, DAG)
routing algorithms
switching (aka multiplexing)
wiring (e.g., choice of media, copper, coax,
fiber)
What really matters
latency
bandwidth
cost
reliability

3
Interconnections (Networks)

Examples (see Figure 7.19, page 633)
Wide Area Network (ATM) 100-1000s nodes 5,000
kilometers
Local Area Networks (Ethernet) 10-1000 nodes
1-2 kilometers
System/Storage Area Networks (FC-AL) 10-100s
nodes 0.025 to 0.1 kilometers per link

a.k.a. end systems, hosts
a.k.a. network, communication subnet
Interconnection Network
4
SAN Storage vs. System

Storage Area Network (SAN) A block I/O oriented
network between application servers and storage
Fibre Channel is an example
Usually high bandwidth requirements, and less
concerned about latency
in 2001 1 Gbit bandwidth and millisecond latency
OK
Commonly a dedicated network (that is, not
connected to another network)
May need to work gracefully when saturated
Given larger block size, may have higher bit
error rate (BER) requirement than LAN

5
SAN vs. NAS

Storage area network
Network-attached storage
Storage virtualization
Continuous data protection

6
SAN Storage vs. System

System Area Network (SAN) A network aimed at
connecting computers
Myrinet is an example
Aimed at High Bandwidth AND Low Latency.
in 2001 gt 1 Gbit bandwidth and 10 microsecond
May offer in order delivery of packets
Given larger block size, may have higher bit
error rate (BER) requirement than LAN

7
More Network Background

Connection of 2 or more networks Internetworking
3 cultures for 3 classes of networks
WAN telecommunications, Internet
LAN PC, workstations, servers cost
SAN Clusters, RAID boxes latency (System A.N.)
or bandwidth (Storage A.N.)
Motivate the interconnection complexity
incrementally

8
ABCs of Networks

Starting Point Send bits between 2 computers
Queue (FIFO) on each end
Information sent called a message
Can send both ways (Full Duplex)
Rules for communication? protocol
Inside a computer
Loads/Stores Request (Address) Response (Data)
Need Request Response signaling

9
A Simple Example

What is the format of mesage?
Fixed? Number bytes?

Request/ Response
Address/Data
1 bit
32 bits
0 Please send data from Address 1 Packet
contains data corresponding to request

Header/Trailer information to deliver a message
Payload data in message (1 word above)

10
Questions About Simple Example

What if more than 2 computers want to
communicate?
Need computer address field (destination) in
packet
What if packet is garbled in transit?
Add error detection field in packet (e.g.,
Cyclic Redundancy Chk)
What if packet is lost?
More elaborate protocols to detect loss
(e.g., NAK, ARQ, time outs)
What if multiple processes/machine?
Queue per process to provide protection
Simple questions such as these lead to more
complex protocols and packet formats gt complexity

11
A Simple Example Revisted

What is the format of packet?
Fixed? Number bytes?

Request/ Response
Address/Data
CRC
2 bits
32 bits
4 bits
00 RequestPlease send data from Address 01
ReplyPacket contains data corresponding to
request 10 Acknowledge request 11 Acknowledge
reply
12
Software to Send and Receive

SW Send steps
1 Application copies data to OS buffer
2 OS calculates checksum, starts timer
3 OS sends data to network interface HW and says
start
SW Receive steps
3 OS copies data from network interface HW to OS
buffer
2 OS calculates checksum, if matches send ACK
if not, deletes message (sender resends when
timer expires)
1 If OK, OS copies data to user address space
and signals application to continue
Sequence of steps for SW protocol
Example similar to UDP/IP protocol in UNIX

13
Low-Latency Message Passing

Reducing data copying
Interrupt coalescing
Decreasing context switch
More efficient DMA transactions
Wither TCP offload engine?

14
Network Performance Measures

Overhead latency of interface vs. Latency
network

15
Universal Performance Metrics
Sender
(processor busy)
Transmission time (size bandwidth)
Time of Flight
Receiver Overhead
Receiver
(processor busy)
Transport Latency
Total Latency
Total Latency Sender Overhead Time of Flight
Message Size BW
Receiver Overhead
Includes header/trailer in BW calculation?
16
Total Latency Example

1000 Mbit/sec., sending overhead of 80 µsec
receiving overhead of 100 µsec.
a 10000 byte message (including the header),
allows 10000 bytes in a single message
2 situations distance 100 m vs. 1000 km
Speed of light 300,000 km/sec
Latency0.01km 80 0.01km / (50 x 300,000)
10000 x 8 / 1000 100 260 µsec
Latency0.5km 80 0.5km / (50 x 300,000)
10000 x 8 / 1000 100 263 µsec
Latency1000km 80 1000 km / (50 x 300,000)
10000 x 8 / 1000 100 6931
Long time of flight gt complex WAN protocol

17
Universal Metrics

Apply recursively to all levels of system
inside a chip, between chips on a board, between
computers in a cluster,
Look at WAN v. LAN v. SAN

18
Simplified Latency Model

Total Latency Overhead Message Size / BW
Overhead Sender Overhead Time of Flight
Receiver Overhead
Example show what happens as vary
Overhead 1, 25, 500 µsec
BW 10,100, 1000 Mbit/sec (factors of 10)
Message Size 16 Bytes to 4 MB (factors of 4)
If overhead 500 µsec, how big a message gt 10
Mb/s?

19
Overhead, BW, Size
Delivered BW
Msg Size

How big are real messages?

20
Measurement Sizes of Message for NFS
Why?

95 Msgs, 30 bytes for packets 200 bytes
gt 50 data transfered in packets 8KB

21
Impact of Overhead on Delivered BW

BW model Time overhead msg size/peak BW

22
Interconnect Issues

Performance Measures
Network Media

23
Network Media
Twisted Pair
Copper, 1mm think, twisted to avoid attenna
effect (telephone) "Cat 5" is 4 twisted pairs in
bundle
Coaxial Cable
Plastic Covering
Used by cable companies high BW, good noise
immunity
Insulator
Copper core
Braided outer conductor
Buffer
Light 3 parts are cable, light source, light
detector. Note fiber is unidirectional need 2
for full duplex
Cladding
Total internal
Fiber Optics
reflection
Transmitter
Receiver
L.E.D
Photodiode
Laser Diode
light
source
Silica core
Cladding
Buffer
24
Fiber

Multimode fiber 62.5 micron diameter vs. the
1.3 micron wavelength of infrared light. Since
wider it has more dispersion problems, limiting
its length at 1000 Mbits/s for 0.1 km, and 1-3 km
at 100 Mbits/s. Uses LED as light
Single mode fiber "single wavelength" fiber (8-9
microns) uses laser diodes, 1-5 Gbits/s for 100s
kms
Less reliable and more expensive, and
restrictions on bending
Cost, bandwidth, and distance of single-mode
fiber affected by power of the light source, the
sensitivity of the light detector, and the
attenuation rate (loss of optical signal strength
as light passes through the fiber) per kilometer
of the fiber cable.
Typically glass fiber, since has better
characteristics than the less expensive plastic
fiber

25
Wave Division Multiplexing Fiber

Send N independent streams on single fiber!
Just use different wavelengths to send and
demultiplex at receiver
WDM in 2000 40 Gbit/s using 8 wavelengths
Plan to go to 80 wavelengths gt 400 Gbit/s!
A figure of merit BW max distance
(Gbit-km/sec)
10X/4 years, or 1.8X per year

26
Compare Media

Assume 40 2.5" disks, each 25 GB, Move 1 km
Compare Cat 5 (100 Mbit/s), Multimode fiber (1000
Mbit/s), single mode (2500 Mbit/s), and car
Cat 5 1000 x 1024 x 8 Mb / 100 Mb/s 23 hrs
MM 1000 x 1024 x 8 Mb / 1000 Mb/s 2.3 hrs
SM 1000 x 1024 x 8 Mb / 2500 Mb/s 0.9 hrs
Car 5 min 1 km / 50 kph 10 min 0.25 hrs
Car of disks high BW media

27
Interconnect Issues

Performance Measures
Network Media
Connecting Multiple Computers

28
Connecting Multiple Computers

Shared Media vs. Switched pairs communicate at
same time point-to-point connections
Aggregate BW in switched network is many times
shared
point-to-point faster since no arbitration,
simpler interface
Arbitration in Shared network?
Central arbiter for LAN?
Listen to check if being used (Carrier Sensing)
Listen to check if collision (Collision
Detection)
Random resend to avoid repeated collisions not
fair arbitration
OK if low utilization

(A. K. A. data switching interchanges,
multistage interconnection networks, interface
message processors)
29
Main Issues

Addressing
Routing
Congestion control
Flow control

30
Connection-Based vs. Connectionless

Telephone operator sets up connection between
the caller and the receiver
Once the connection is established, conversation
can continue for hours
Share transmission lines over long distances by
using switches to multiplex several conversations
on the same lines
Time division multiplexing divide B/W
transmission line into a fixed number of slots,
with each slot assigned to a conversation
Problem lines busy based on number of
conversations, not amount of information sent
Advantage reserved bandwidth

31
Connection-Based vs. Connectionless

Connectionless every package of information must
have an address gt packets
Each package is routed to its destination by
looking at its address
Analogy, the postal system (sending a letter)
also called Statistical multiplexing
Note Split phase buses are sending packets

32
Routing Messages

Shared Media
Broadcast to everyone
Switched Media needs real routing. Options
Source-based routing message specifies path to
the destination (changes of direction)
Virtual Circuit circuit established from source
to destination, message picks the circuit to
follow
Destination-based routing message specifies
destination, switch must pick the path
deterministic always follow same path
adaptive pick different paths to avoid
congestion, failures
Randomized routing pick between several good
paths to balance network load

33
Deterministic Routing Examples

mesh dimension-order routing
(x1, y1) -gt (x2, y2)
first ?x x2 - x1,
then ?y y2 - y1,
hypercube edge-cube routing
X xox1x2 . . .xn -gt Y yoy1y2 . . .yn
R X xor Y
Traverse dimensions of differing address in order
tree common ancestor
Deadlock free?

34
Store and Forward vs. Cut-Through

Store-and-forward policy each switch waits for
the full packet to arrive in switch before
sending to the next switch (good for WAN)
Cut-through routing or worm hole routing switch
examines the header, decides where to send the
message, and then starts forwarding it
immediately
In worm hole routing, when head of message is
blocked, message stays strung out over the
network, potentially blocking other messages
(needs only buffer the piece of the packet that
is sent between switches).
Cut through routing lets the tail continue when
head is blocked, and putting the whole message
into a single switch. (Requires a buffer large
enough to hold the largest packet).

35
Cut-Through vs. Store and Forward

Advantage
Latency reduces from function ofnumber of
intermediate switches X by the size of the packet
to time for 1st part of the packet to
negotiate the switches the packet size
interconnect BW

36
Congestion Control

Packet switched networks do not reserve
bandwidth this leads to contention (connection
based limits input)
Solution prevent packets from entering until
contention is reduced (e.g., freeway on-ramp
metering lights)
Options
Packet discarding If packet arrives at switch
and no room in buffer, packet is discarded (e.g.,
UDP)
Flow control between pairs of receivers and
senders use feedback to tell sender when
allowed to send next packet
Back-pressure separate wires to tell to stop
Window give original sender right to send N
packets before getting permission to send more
overlaps latency of interconnection with
overhead to send receive packet (e.g., TCP),
adjustable window
Choke packets aka rate-based Each packet
received by busy switch in warning state sent
back to the source via choke packet. Source
reduces traffic to that destination by a fixed
(e.g., ATM)

37
Protocols HW/SW Interface

Internetworking allows computers on independent
and incompatible networks to communicate reliably
and efficiently
Enabling technologies SW standards that allow
reliable communications without reliable networks
Hierarchy of SW layers, giving each layer
responsibility for portion of overall
communications task, called protocol families or
protocol suites
Transmission Control Protocol/Internet Protocol
(TCP/IP)
This protocol family is the basis of the Internet
IP makes best effort to deliver TCP guarantees
delivery
TCP/IP used even when communicating locally NFS
uses IP even though communicating across
homogeneous LAN

38
Connecting Networks

Bridges connect LANs together, passing traffic
from one side to another depending on the
addresses in the packet.
operate at the Ethernet protocol level
usually simpler and cheaper than routers
Routers or Gateways these devices connect LANs
to WANs or WANs to WANs and resolve incompatible
addressing.
Generally slower than bridges, they operate at
the internetworking protocol (IP) level
Routers divide the interconnect into separate
smaller subnets, which simplifies manageability
and improves security
Cisco is major supplier basically special
purpose computers

39
Virtual LAN

Layer2 technology that tries to achieve what
Layer3 routers can do limit broadcast traffic
Distributed spanning tree protocol (802.1D)
Per-tree spanning tree
VLAN to emulate ATM
Transparent reliable multicast
IGMP snooping

40
Wireless Networks

Media can be air as well as glass or copper
Radio wave is electromagnetic wave propagated by
an antenna
Radio waves are modulated sound signal
superimposed on stronger radio wave which carries
sound signal, called carrier signal
Radio waves have a wavelength or frequency
measure either length of wave or number of waves
per second (MHz) long waves gt low frequencies,
short waves gt high frequencies
Tuning to different frequencies gt radio receiver
pick up a signal.
FM radio stations transmit on band of 88 MHz to
108 MHz using frequency modulations (FM) to
record the sound signal

41
Issues in Wireless

Wireless often gt mobile gt network must
rearrange itself dynamically
Subject to jamming and eavesdropping
No physical tape
Cannot detect interception
Power
devices tend to be battery powered
antennas radiate power to communicate and little
of it reaches the receiver
As a result, raw bit error rates are typically a
thousand to a million times higher than copper
wire

42
Reliability of Wires Transmission

bit error rate (BER) of wireless link determined
by received signal power, noise due to
interference caused by the receiver hardware,
interference from other sources, and
characteristics of the channel
Path loss power to overcome interference
Shadow fading blocked by objects (walls,
buildings)
Multipath fading interference between multiple
version of signals arriving different times
Interference reuse of frequency or from adjacent
channels

43
2 Wireless Architectures

Base-station architectures
Connected by land lines for longer distance
communication, and the mobile units communicate
only with a single local base station
More reliable since 1-hop from land lines
Example cell phones
Peer-to-peer architectures
Allow mobile units to communicate with each
other, and messages hop from one unit to the next
until delivered to the desired unit
More reconfigurable

44
Unified P2P Architecture

Completely distributed system dont even know
who to talk to ?
Advantages scalability, fault tolerance, and
anonymity
Examples
KaZaA
Routing protocol for wired networks
Routing protocol for wireless networks

45
Cellular Telephony

Exploit exponential path loss to reuse same
frequency at spatially separated locations,
thereby greatly increasing customers served
Divide region into nonoverlaping hexagonal cells
(2-10 mi. diameter) which use different
frequencies if nearby, reusing a frequency when
cells far apart so that mutual interference OK
Intersection of three hexagonal cells is a base
station with transmitters and antennas
Handset selects a cell based on signal strength
and then picks an unused radio channel
To properly bill for cellular calls, each
cellular phone handset has an electronic serial
number

46
Cellular Telephony II

Orginal analog design frequencies set for each
direction pair called a channel
869.04 to 893.97 MHz, called the forward path
824.04 MHz to 848.97 MHz, called the reverse path
Cells might have had between 4 and 80 channels
Several digital successors
Code division multiple access (CDMA) uses a wider
radio frequency band
time division multiple access (TDMA)
global system for mobile communication (GSM)
International Mobile Telephony 2000 (IMT-2000)
which is based primarily on two competing
versions of CDMA and one TDMA, called Third
Generation (3G)

47
Wireless Networking vs. Communications

The name of the game is wireless communications
modulation, MIMO, diversity
Networking part routing, transport protocol,
handoff, security

48
Practical Issues for Inteconnection Networks

Connectivity max number of machines affects
complexity of network and protocols since
protocols must target largest size
Connection Network Interface to computer
Where in bus hierarchy? Memory bus? Fast I/O bus?
Slow I/O bus? (Ethernet to Fast I/O bus,
Inifiband to Memory bus since it is the Fast I/O
bus)
SW Interface does software need to flush caches
for consistency of sends or receives?
Programmed I/O vs. DMA? Is NIC in uncachable
address space?

49
Practical Issues for Inteconnection Networks

Standardization advantages
low cost (components used repeatedly)
stability (many suppliers to chose from)
Standardization disadvantages
Time for committees to agree
When to standardize?
Before anything built? gt Committee does design?
Too early suppresses innovation
Reliability (vs. availability) of interconnect

50
Practical Issues

Interconnection SAN LAN WAN
Example Inifiband Ethernet ATM
Standard Yes Yes Yes
Fault Tolerance? Yes Yes Yes
Hot Insert? Yes Yes Yes
Standards required for WAN, LAN, and likely SAN!
Fault Tolerance Can nodes fail and still deliver
messages to other nodes?
Hot Insert If the interconnection can survive a
failure, can it also continue operation while a
new node is added to the interconnection?

51
Cross-Cutting Issues for Networking

Efficient Interface to Memory Hierarchy vs. to
Network
SPEC ratings gt fast to memory hierarchy
Writes go via write buffer, reads via L1 and L2
caches
Example 40 MHz SPARCStation(SS)-2 vs 50 MHz
SS-20, no L2 vs 50 MHz SS-20 with L2 I/O bus
latency different generations
SS-2 combined memory, I/O bus gt 200 ns
SS-20, no L2 2 busses 300ns gt 500ns
SS-20, w L2 cache miss500ns gt 1000ns

52
Crosscutting Smart Switch vs. Smart Network
Interface Card

Inexpensive NIC gt Ethernet standard in all
computers
Inexpensive switch gt Ethernet used in home
networks

53
Cluster

LAN switches gt high network bandwidth and
scaling was available from off the shelf
components
2001 Cluster collection of independent
computers using switched network to provide a
common service
Many mainframe applications run more "loosely
coupled" machines than shared memory machines
(next chapter/week)
databases, file servers, Web servers,
simulations, and multiprogramming/batch
processing
Often need to be highly available, requiring
error tolerance and reparability
Often need to scale

54
Cluster Drawbacks

Cost of administering a cluster of N machines
administering N independent machines vs. cost of
administering a shared address space N processors
multiprocessor administering 1 big machine
Clusters usually connected using I/O bus, whereas
multiprocessors usually connected on memory bus
Cluster of N machines has N independent memories
and N copies of OS, but a shared address
multi-processor allows 1 program to use almost
all memory
DRAM prices has made memory costs so low that
this multiprocessor advantage is much less
important in 2001

55
Cluster Advantages

Error isolation separate address space limits
contamination of error
Repair Easier to replace a machine without
bringing down the system than in an shared memory
multiprocessor
Scale easier to expand the system without
bringing down the application that runs on top of
the cluster
Cost Large scale machine has low volume gt fewer
machines to spread development costs vs. leverage
high volume off-the-shelf switches and computers
Amazon, AOL, Google, Hotmail, Inktomi, WebTV, and
Yahoo rely on clusters of PCs to provide services
used by millions of people every day

56
Addressing Cluster Weaknesses

Network performance SAN, especially Inifiband,
may tie cluster closer to memory
Maintenance separate of long term storage and
computation
Computation maintenance
Clones of identical PCs
3 steps reboot, reinstall OS, recycle
At 1000/PC, cheaper to discard than to figure
out what is wrong and repair it?
Storage maintenance
If separate storage servers or file servers,
cluster is no worse?

57
Clusters and TPC Benchmarks

Shared Nothing database (not memory, not disks)
is a match to cluster
2/2001 Top 10 TPC performance 6/10 are clusters
(4 / top 5)

58
Putting it all together Google

Google search engine that scales at growth
Internet growth rates
Search engines 24x7 availability
Google 12/2000 70M queries per day, or AVERAGE
of 800 queries/sec all day
Response time goal lt 1/2 sec for search
Google crawls WWW and puts up new index every 4
weeks
Stores local copy of text of pages of WWW
(snippet as well as cached copy of page)
3 collocation sites (2 CA 1 Virginia)
6000 PCs, 12000 disks almost 1 petabyte!

59
Hardware Infrastructure

VME rack 19 in. wide, 6 feet tall, 30 inches
deep
Per side 40 1 Rack Unit (RU) PCs 1 HP Ethernet
switch (4 RU) Each blade can contain 8
100-Mbit/s EN or a single 1-Gbit Ethernet
interface
Frontback gt 80 PCs 2 EN switches/rack
Each rack connects to 2 128 1-Gbit/s EN switches
Dec 2000 40 racks at most recent site

60
Google PCs

2 IDE drives, 256 MB of SDRAM, modest Intel
microprocessor, a PC mother-board, 1 power supply
and a few fans.
Each PC runs the Linix operating system
Buy over time, so upgrade componentspopulated
between March and November 2000
microprocessors 533 MHz Celeron to an 800 MHz
Pentium III,
disks capacity between 40 and 80 GB, speed 5400
to 7200 RPM
bus speed is either 100 or 133 MH
Cost 1300 to 1700 per PC
PC operates at about 55 Watts
Rack gt 4500 Watts , 60 amps

61
Reliability

For 6000 PCs, 12000s, 200 EN switches
20 PCs will need to be rebooted/day
2 PCs/day hardware failure, or 2-3 / year
5 due to problems with motherboard, power
supply, and connectors
30 DRAM bits change errors in transmission
(100 MHz)
30 Disks fail
30 Disks go very slow (10-3 expected BW)
200 EN switches, 2-3 fail in 2 years
6 Foundry switches none failed, but 2-3 of 96
blades of switches have failed (16 blades/switch)
Collocation site reliability
1 power failure,1 network outage per year per
site
Bathtub for occupancy

62
Google Performance Serving

How big is a page returned by Google? 16KB
Average bandwidth to serve searches
70,000,000/day x 16,750 B x 8 bits/B
24 x 60 x 60
9,378,880 Mbits/86,400 secs
108 Mbit/s

63
Google Performance Crawling

How big is a text of a WWW page? 4000B
1 Billion pages searched
Assume 7 days to crawl
Average bandwidth to crawl
1,000,000,000/pages x 4000 B x 8 bits/B
24 x 60 x 60 x 7
32,000,000 Mbits/604,800 secs
59 Mbit/s

64
Google Performance Replicating Index

How big is Google index? 5 TB
Assume 7 days to replicate to 2 sites, implies BW
to send BW to receive
Average bandwidth to replicate new index
2 x 2 x 5,000,000 MB x 8 bits/B
24 x 60 x 60 x 7
160,000,000 Mbits/604,800 secs
260 Mbit/s

65
Co-location Sites

Allow scalable space, power, cooling and network
bandwidth plus provide physical security
charge about 500 to 750 per Mbit/sec/month
if your continuous use measures 1- 2 Gbits/second
to 1500 to 2000 per Mbit/sec/month
if your continuous use measures 1-10 Mbits/second
Rack space costs 800 -1200/month, and drops by
20 if gt 75 to 100 racks (1 20 amp circuit)
Each additional 20 amp circuit per rack costs
another 200 to 400 per month
PGE 12 megawatts of power, 100,000 sq.
ft./building, 10 sq. ft./rack gt 1000 watts/rack

66
Google Performance Total

Serving pages 108 Mbit/sec/month
Crawling 59 Mbit/sec/week, 15 Mbit/s/month
Replicating 260 Mbit/sec/week, 65 Mb/s/month
Total roughly 200 Mbit/sec/month
Googles Collocation sites have OC48
(2488 Mbit/sec) link to Internet
Bandwidth cost per month? 150,000 to 200,000
1/2 BW grows at 20/month

67
Google Costs

Collocation costs 40 racks _at_ 1000 per month
500 per month for extra circuits
60,000 per site, 3 sites
180,000 for space
Machine costs
Rack 2k 80 1500/pc 2 1500/EN
125k
40 racks 2 Foundry switches _at_100,000
5M
3 sites 15M
Cost today is 10,000 to 15,000 per TB

68
Comparing Storage Costs 1/2001

Google site, including 3200 processors and 0.8 TB
of DRAM, 500 TB (40 racks) 10k - 15k/ TB
Compaq Cluster with 192 processors, 0.2 TB of
DRAM, 45 TB of SCSI Disks (17 racks) 115k/TB
(TPC-C)
HP 9000 Superdome 48 processors, 0.25 TB DRAM,
19 TB of SCSI disk (23 racks) 360k/TB (TPC-C)

69
Putting It All Together Cell Phones

1999 280M handsets sold 2001 500M
Radio steps/components Receive/transmit
Antenna
Amplifier
Mixer
Filter
Demodulator
Decoder

70
Putting It All Together Cell Phones

about 10 chips in 2000, which should shrink, but
likely separate MPU and DSP
Emphasis on energy efficiency

From How Stuff Works on cell phones
www.howstuffworks.com
71
Cell phone steps (protocol)

Find a cell
Scans full BW to find stronger signal every 7
secs
Local switching office registers call
records phone number, cell phone serial number,
assigns channel
sends special tone to phone, which cell acks if
correct
Cell times out after 5 sec if doesn't get
supervisory tone
Communicate at 9600 b/s digitally (modem)
Old style message repeated 5 times
AMPS had 2 power levels depending on distance
(0.6W and 3W)

72
Frequency Division Multiple Access (FDMA)

FDMA separates the spectrum into distinct voice
channels by splitting it into uniform chunks of
bandwidth
!st generation analog

From How Stuff Works on cell phones
www.howstuffworks.com
73
Time Division Multiple Access (TDMA)

a narrow band that is 30 kHz wide and 6.7 ms long
is split time-wise into 3 time slots.
Each conversation gets the radio for 1/3 of time.
Possible because voice data converted to digital
information is compressed so
Therefore, TDMA has 3 times capacity of analog
GSM implements TDMA in a somewhat different and
incompatible way from US (IS-136) also encrypts
the call

From How Stuff Works on cell phones
www.howstuffworks.com
74
Code Division Multiple Access (CDMA)

CDMA, after digitizing data, spreads it out over
the entire bandwidth it has available.
Multiple calls are overlaid over each other on
the channel, with each assigned a unique sequence
code.
CDMA is a form of spread spectrum All the users
transmit in the same wide-band chunk of spectrum.
Each user's signal is spread over the entire
bandwidth by a unique spreading code. same unique
code is used to recover the signal.