Networking%20Research%20

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Title: Networking%20Research%20

1
Networking Research Vision and Opportunities

Henning Schulzrinne
Dept. of Computer Science
Columbia University
hgs_at_cs.columbia.edu

2
Overview

Network research topics
will focus on L3 and above
mostly on software
optical and electronic switch work continues
systems perspective
Some samples of IRT research
location-based services
service creation
network reliability
End-to-end QoS estimation

3
Networking is getting into middle years
idea current
IP 1969, 1980? 1981
TCP 1974 1981
telnet 1969 1983
ftp 1980 1985
4
Technologies at 30 years

Other technologies at similar maturity level
air planes 1903 1938 (Stratoliner)
cars 1876 1908 (Model T)
analog telephones 1876 1915 (transcontinental
telephone)
railroad 1800s -- ?

5
Maturing network research

Old questions
Can we make X work over packet networks?
All major dedicated network applications (flight
reservations, embedded systems, radio, TV,
telephone, fax, messaging, ) are now available
on IP
Can we get M/G/T bits to the end user?
Raw bits everywhere any media, anytime,
anywhere
New questions
Dependency on communications ? Can we make the
network reliable?
Can non-technical users use networks without
becoming amateur sys-admins? ? auto/zeroconfigurat
ion, autonomous computing, self-healing networks,
Can we prevent social and financial damage
inflicted through networks (viruses, spam, DOS,
identity theft, privacy violations, )?

6
Standardization

Really two facets of standardization
public, interoperable description of protocol,
but possibly many (Tanenbaum)
reduction to 1-3 common technologies
LAN Arcnet, tokenring, ATM, FDDI, DQDB, ?
Ethernet
WAN IP, X.25, OSI ? IP
Have reached phase 2 in most cases, with RPC
(SOAP) and presentation layer (XML) most recent
'conversions'

7
Observations on progress

1960s military ? professional ? consumer
now, often reversed
Oscillate convergence ? divergence
continued convergence clearly at physical layer
niches larger ? support separate networks
Communications technologies rarely disappear (as
long as operational cost is low)
exceptions
telex, telegram, semaphores ? fax, email
X.25 OSI, X.400 ? IP, SMTP
analog cell phones

8
History of networking

History of networking non-network applications
migrate
postal intracompany mail, fax ? email, IM
broadcast TV, radio
interactive voice/video communication ? VoIP
information access ? web, P2P
disk access ? iSCSI, Fiberchannel-over-IP

9
Transition of networking

Maturity ? cost dominates
can get any number of bits anywhere, but at
considerable cost and complexity
casually usable bit density still very low
Specialized ? commodity
OPEX ( people) dominates
installed and run by 'amateurs'
need low complexity, high reliability

10
Network evolution

Only three modes, now thoroughly explored
packet/cell-based
message-based (application data units)
session-based (circuits)
Replace specialized networks
left to do embedded systems
need cost(CPU network) lt 10
cars
industrial (manufacturing) control
commercial buildings (lighting, HVAC, security
now LONworks)
remote controls, light switches
keys replaced by biometrics

11
Commercial access cost (T1)
12
Transit cost (OC-3, NY London)
13
Disk storage cost (IDE)
14
Research directions

Whats promising/interesting two different
axes
Intellectual merit ? interesting analysis,
broadly applicable,
Satisfies practical needs ? may not be a
scientific breakthrough
Related, but Ill (mostly) ignore
Whats fashionable/hot"

15
Whats fashionable (and not)

Judging from Infocom submissions and NSF panels
Security of any sort
Peer-to-peer networks
Ad-hoc and sensor networks
Overlay networks
Network measurements
Whats not
QoS scheduling, admission control,
Active networks
(Native) multicast

16
Observations on network research

Frustration with inability to change network
infrastructure in less than 10 -- 20 year
horizons
IPv6
Layer-3 multicast
QoS
Security
Network research community has dismal track
record for new applications
web, IM, P2P, vs. video-on-demand
Disconnect from standardization
Few attempts to bring research work into
standards bodies
Standards bodies slow to catch up (e.g., P2P)

17
Network research

Old goal "new universal network"
IP, OSI, ATM
New goal "niche networks"
may claim universality
peer-to-peer, ad hoc, sensor, mesh,
New research community realizations
difficulty in rolling out new network ?
incrementalism
spectrum issues (open spectrum, SDR, )

18
Infrastructure research questions Scaling,
Reliability, Security

Scaling
no major changes for 20 years (link-state, DV,
etc.)
two-layer (intra/inter) ? other routing paradigms
Reliability
reduce operator errors (e.g., XCONF effort in
IETF)
faster convergence in routing protocols (BGP ? up
to 20-30 minutes!)
Security
secure routing protocols
DOS prevention (pushback, source discovery)

19
Scaling practical issues

Scaling is only backbone problem
Depends on network evolution
continuing addition of AS to flat space ? deep
trouble
additional hierarchy

20
QoS

QoS is meaningless to users
care about service availability ? reliability
as more and more value depends on network
services, can't afford random downtimes

21
Transport layer

After XTP flop, flurry of new protocols SCTP,
DDCP, UDP-lite
fill in gaps in TCP/UDP
flow control without reliability
multiple logical streams with one flow control
stream (cf. HTTP/1.1)
Issues of very fat pipes
single packet loss can wipe out effective
throughput

22
Applications

Transition of custom protocols to XML, SOAP?
but this is the not the first try (DCE, SunRPC,
COM, Java RMI, Corba, )
Scalable event systems (research)
Presence (SIP/SIMPLE, Jabber, )
P2P systems
Application-layer routing, multicast, discovery,

23
New applications

New bandwidth-intensive applications
Reality-based networking
(security) cameras
Distributed games often require only
low-bandwidth control information
current game traffic VoIP
Computation vs. storage vs. communications
communications cost has decreased less rapidly
than storage costs

24
Security challenges

DOS, security attacks ? permissions-based
communications
only allow modest rates without asking
effectively, back to circuit-switched
Higher-level security services ? more
application-layer access via gateways, proxies,
User identity
problem is not availability, but rather
over-abundance

25
Fundamental re-thinking

"Hour glass" with single address space ? multiple
gatewayed networks with separate address spaces
diversity vs. uniformity
Application-neutral connectivity ? filtered
restricted (? tunneling over port 80)
Send first, ask later ? permission-based
networking
old default no (mutual) authentication
new only authenticated users/applications

26
Wildcards

Quantum computing
Teleportation

27
Ubiquitous SIP

Henning Schulzrinne
(with Stefan Berger, Stelios Sidiroglou, Kundan
Singh, Xiaotao Wu, Weibin Zhao and the RPIDS
authors)
Columbia University IRT Lab
Hewlett Packard March 2003

28
Overview

What is ubiquitous computing?
Core ubiquitous communications functionality
Brief introduction to SIP
Ubiquitous computing in SIP and SLP
On-going work at Columbia

29
What is ubiquitous computing?

Ubiquitous computing has as its goal the
enhancing computer use by making many computers
available throughout the physical environment,
but making them effectively invisible to the
user. (Weiser, 1993)
Ubiquitous computing is not virtual reality, it
is not a Personal Digital Assistant (PDA) such as
Apple's Newton, it is not a personal or intimate
computer with agents doing your bidding. Unlike
virtual reality, ubiquitous computing endeavers
to integrate information displays into the
everyday physical world. It considers the nuances
of the real world to be wonderful, and aims only
to augment them. (Weiser, 1993)

30
Ubiquitous computing aspects

Also related to pervasive computing
Mobility, but not just cell phones
Computation and communications
Integration of devices
borrow capabilities found in the environment ?
composition into logical devices
seamless mobility ? session mobility
adaptation to local capabilities
environment senses instead of explicit user
interaction
from small dumb devices to PCs
light switches and smart wallpaper

31
Components of ubiquitous communications

Service discovery ? discover devices
Service mobility ? configuration information
moves to new devices
Event notification ? for context awareness
Context-awareness ? location, user actions,
location properties,

32
Example ubicomp projects

Ambient Devices
EU IST Disappearing Computer
Project Aura, CMU ? user attention
UNC office of real soon now
augmented surfaces Reki99
Microsoft Easy Living
Oxygen, MIT
Portolano, Univ. of Washington
Endeavour, Berkeley
CoolTown, HP Labs

33
Ubiquitous computing using SIP whats different?

Traditionally, focus on closed environments (lab,
single company, home, )
Often, proprietary protocols ? self-contained
environment
Here,
operate across Internet (? no Corba)
trusted, semi-trusted and untrusted participants
use standard protocol mechanisms where possible
make minimal assumptions on homogeneity
respect user privacy

34
What is SIP?

Session Initiation Protocol ? protocol that
establishes, manages (multimedia) sessions
also used for IM, presence event notification
uses SDP to describe multimedia sessions
Developed at Columbia U. (with others)
Standardized by IETF, 3GPP (for 3G wireless),
PacketCable
About 60 companies produce SIP products
Microsofts Windows Messenger (4.7) includes SIP

35
Basic SIP message flow
36
SIP trapezoid
37
SIP event notification

Named events
Typically, used for events within conferences
(Alice joined) and call legs (e.g., call
transfer)
Supports arbitrary notification bodies, typically
XML

SUBSCRIBE sipalice_at_vmail.example.com SIP/2.0 To
ltsipalice_at_example.comgt From ltsipalice_at_example.c
omgttag78923 Call-Id 1349882_at_alice-phone.example
.com Contact ltsipalice_at_alice-phone.example.comgt
NOTIFY sipalice_at_alice-phone.example.com
SIP/2.0 Event message-summary Subscription-Stat
e active Messages-Waiting yes Message-Account
sipalice_at_vmail.example.com Voice-Message 2/8
(0/2)
38
SIP event architecture

Does not try to route notifications (application
layer multicast) as in SIENA
Filtering at PA under discussion (for
low-bandwidth devices)
rate
content
But most ubicomp notification groups are probably
small
and message volume not likely to provide much
bandwidth saving via network-based filtering
Greatly simplifies trust model no intermediaries
that need to inspect content
can encrypt via S/MIME
However, can build redistribution exploders and
list subscriptions (subscribe to
engineering_at_hp.com)

39
SIP presence architecture
REGISTER
SUBSCRIBE
watcher
PA
Alice
NOTIFY
Bob
lt?xml version"1.0" encoding"UTF-8"?gt ltppresence
xmlnsp"urn" entity"presalice_at_example
.com"gt ltptuple id"sg89ae"gt ltpstatusgt
ltpbasicgtopenlt/pbasicgt lt/pstatusgt
ltpcontactgttel09012345678lt/pcontactgt lt/ptuplegt
lt/ppresencegt
PUAs
PUBLISH
40
Session mobility

Walk into office, switch from cell phone to desk
phone
call transfer problem ? SIP REFER
related problem split session across end devices
e.g., wall display desk phone PC for
collaborative application
assume devices (or stand-ins) are SIP-enabled
third-party call control

41
Session mobility via 3PCC
pc42
INVITE speakerphone maudio cpc42
192.0.2.1
INVITE pc42 mvideo c192.0.2.7 maudio c192.0.2.
1
INVITE display mvideo cpc42
192.0.2.7
42
How to find services?

Two complementary developments
smaller devices carried on user instead of
stationary devices
devices that can be time-shared
large plasma displays
projector
hi-res cameras
echo-canceling speaker systems
wide-area network access
Need to discover services in local environment
SLP (Service Location Protocol) allows querying
for services
find all color displays with at least XGA
resolution
slp//example.com/SrvRqst?public?typeprinter
SLP in multicast mode
SLP in DA mode
Need to discover services before getting to
environment
is there a camera in the meeting room?
SLP extension find remote DA via DNS SRV

43
Service Location Protocol (SLP)

Version 2 standardized June 1999

SrvRqst
SA
UA
SA
SrvRply
SrvReg
DA
SrvReg
SrvRqst
DAAdvert
44
SLP attribute example
URL serviceprinterlpr//igore.wco.ftp.com/draft
scope-list Development
Language tag en
Attributes (NameIgore),(DescriptionFor developers only), (ProtocolLPR),(location-description12th floor), (OperatorJames Dornan \3cdornan_at_monster\3e), (media-sizena-letter),(resolutionres-600),x-OK
45
Other service location mechanism

DNS SRV/NAPTR
DNS TXT records (Apple Rendezvous) ? DNS-SD
UPnP uses SSDP
multicast HTTP over UDP

M-SEARCH HTTP/1.1 S uuidijklmnop-7dec-11d0-a76
5-00a0c91e6bf6 Host 239.255.255.250reservedSSDPp
ort Man "ssdpdiscover ST gefridge MX
3 HTTP/1.1 200 OK S uuidijklmnop-7dec-11d0-a765
-00a0c91e6bf6 Ext Cache-Control no-cache"Ext",
max-age 5000 ST gefridge USN
uuidabcdefgh-7dec-11d0-a765-00a0c91e6bf6 AL
ltblenderixlgtlthttp//foo/bargt
46
Service mobility

Allow access to service parameters anywhere
payphone problem
address book
incoming call rules
source name (SIP From)
Existing solutions
SIM card ? cumbersome to change
synchronization (e.g., Palm) ? not suitable for
borrowed devices
Server-based services ? easier with SIP
(service-routing), if carrier allows
Emerging solutions for SIP systems
Small user token (smart card, RFID, i-button)
identifying user
Temporarily download configuration from home
server

47
Location-based services

3 major factors for services and personalization
universal persona (certs, IM, email, SIP) ?
time (NTP) ?
space ? not much yet
Most location-based services
"find nearest X"
customized popup ads eagerly await!
911
We focus on computational, network and
communication services in the environment
current and future locations

48
Locations

Geographic location
latitude, longitude, altitude, velocity, heading
Civil location (? postal location!)
street address, city
some countries are a bit difficult
Categorical
office, library, theater, hospital,
Behavioral
public location, don't expect privacy
silence is encouraged, don't ring the phone

49
Determining locations

SIP entities are often far away from physical
user or his current network (intentionally)
For many devices, cant afford hardware to
determine location
different precision requirements
in Fayette County (within driving distance of
service or person)
on campus
in room 815
in corner, talking to Bob
GPS doesnt work indoors, but Assisted GPS
(A-GPS) may
Use location beacons BlueTooth, 802.11
802.11 requires overlapping APs
may not offer network connectivity
see our 7DS project offer local content
location
Physically close by network entities
DHCP (same broadcast domain)
PPP (tail circuit)
Not always true with VPNs, but end system knows
that its using a VPN

50
DHCP for locations

modified dhcpd (ISC) to generate location
information
use MAC address backtracing to get location
information

8020abd5d
DHCP server
CDP SNMP 8020abd5d ? 458/17
DHCP answer staDC locRm815 lat38.89868
long77.03723
458/17 ? Rm. 815 458/18 ? Rm. 816
51
Determining locations

For many devices, cant afford hardware to
determine location
Implementing BlueTooth-based location sensor
networks
CU 7DS project offer local content location
Developing programmable active badges with IR and
RF capabilities

52
DHCP for locations

Proposal DHCP extensions for geographic and
civil location
geographic resolution (bits), long/lat, altitude
(meters or floors)
civil
what end system, switch or DHCP server
hierarchical subdivisions, from country to
street, landmark name, occupant
Also, some LAN switches broadcast port and switch
identification
CDP for Cisco, EDP for Extreme Networks
Can also use backtracking via SNMP switch tables
locally implemented for emergency services (Perl
sip-cgi script)

53
Location-based services

Services
Location-aware call routing
do not forward call if time at callee location
is 11 pm, 8 am
only forward time-for-lunch if destination is on
campus
contact nearest emergency call center
do not ring phone if Im in a theater
send delivery_at_pizza.com to nearest branch
Location-based events
subscribe to locations, not people
Alice has entered the meeting room
subscriber may be device in room ? our lab stereo
changes CDs for each person that enters the room
Person location events
Were implementing SIP, caller-preferences and
CPL extensions for these services

54
SIP extensions for location-based services

Location information is highly sensitive
complete tracking of person
stalkers and burglars would kill for this
information
IETF GEOPRIV principle target can control
dissemination of location information
restrict time of day, information (location,
heading, velocity) resolution, number of times
queried, destination, retention,
Alice is in time zone MET may be ok for
strangers, but Alice is at 41.872833 N,
087.624417 W, heading NE at 45 mph is not
GEOPRIV still defining application scenarios
in many cases, easiest to include location
information in-band with protocol, as this
avoids delegating authorization
otherwise, need to give access key to database to
recipient
we propose adding SIP Location header field

55
RPIDS rich presence data

Basic IETF presence (CPIM) only gives you
contact information (SIP, tel URI)
priority
open or closed
Want to use presence to guide communications

watcher
everything
PA
PUA
watcher
"vague"
PUBLISH
watcher
NOTIFY
CPL
INVITE
56
Aside SIP caller preferences

SIP core philosophy many devices, one identifier
Address people, not plastic

57
Aside SIP caller preferences

But caller sometimes has preferences among
devices
SIP caller guides call routing
I hate voicemail!
I hate people!
I prefer voicemail
Multilingual lines
Caller proposes, callee disposes

sipisabel_at_a.comlanguages"es" sipisabel_at_a.coml
anguages"en"q0.2
INVITE sipsales_at_a.com Accept-Contact
languages"en"
REGISTER
INVITE
sipbob_at_a.comlanguages"en"
58
RPIDS Rich presence data

Integrates caller preferences information into
presence announcements
ltactivitygt on-the-phone, away, appointment,
holiday, meal, meeting, steering, in-transit,
travel, vacation, busy, permanent-absence
ltplacetypegt home, office, public
ltprivacygt public, private, quiet
ltfromgt, ltuntilgt status validity
ltidlegt activity for device
ltrelationshipgt family, associate, assistant,
supervisor
ltclassgt labeling and grouping
lticongt, ltcardgt, ltinfogt labeling presentities

59
RPIDS example

lttuple id"7c8dqui"gt
ltstatusgt
ltbasicgtopenlt/basicgt
ltcontactgtsipsecretary_at_example.comlt/contactgt
ltcapcapabilitiesgt ltcapfeature
name"Media"gt
ltcapvaluegtvoicelt/capvaluegt
ltcapvalue negated"true"gtmessagelt/capval
uegt
lt/capfeaturegt
lt/capcapabilitiesgt
lt/statusgt
lteprelationshipgtassistantlt/eprelationshipgt
ltnotegtMy secretarylt/notegt
lt/tuplegt

60
Event filtering

Events are core attribute of ubiquitous computing
systems
tell devices about people actions
tell people about device presence
e.g., Alice has entered Room 815
devices that know Alices preferences subscribe
to Alice
locations may also have presence
e.g., for occupancy sensors, switches

61
Location filtering language

SIP presence information will be updated using
REGISTER and UPDATE
Need to constrain
who is allowed to see what detail ? presentity
privacy
who wants to see what detail
how often
what granularity of change
Proposal to allow SUBSCRIBE to include frequency
limitation
Working on CPL-like language invoked (logically)
at publication time
classes of users, e.g., based on entry in my
address book
classes get mapped to restriction
12 bits of long/lat resolution, 6 bits of
altitude resolution, 0 bits of velocity
time zone only, category only
watchers can then add filters that restrict the
delivery
location difference gt threshold
entering or leaving certain area
entering or leaving category or behavioral type

62
Columbia SIP servers (CINEMA)
Telephone switch
Local/long distance 1-212-5551212
rtspd media server
Quicktime
Single machine
RTSP
sipconf Conference server
RTSP clients
Department PBX
sipum Unified messaging
Internal Telephone Extn 7040
713x
sipd Proxy, redirect, registrar server
SQL database
SIP/PSTN Gateway
Web based configuration
SNMP (Network Management)
Extn 7134
H.323
Extn 7136
siph323 SIP-H.323 translator
NetMeeting
xiaotaow_at_cs
63
Location-based services in CINEMA

Initial proof-of-concept implementation
Integrate devices
lava lamp via X10 controller ? set personalized
light mood setting
Pingtel phone ? add outgoing line to phone and
register user
painful needs to be done via HTTP POST request
stereo ? change to audio CD track based on user
Sense user presence and identity
passive infrared (PIR) occupancy sensor
magnetic swipe card
ibutton
BlueTooth equipped PDA
IRRF badge (in progress)
RFID (future)
biometrics (future)

64
CINEMA system
65
All-SIP implementation
66
Service creation

Promise of faster service creation
traditionally, only vendors (and sometimes
carriers)
learn from web models

programmer, carrier end user
network servers SIP servlets, sip-cgi CPL
end system VoiceXML VoiceXML (voice), LESS
67
sip-cgi

web common gateway interface (cgi)
oldest (and still most commonly used) interface
for dynamic content generation
web server invokes process and passes HTTP
request via
stdin (POST body)
environment variables ? HTTP headers, URL
arguments as POST body or GET headers
(?arg1var1arg2var2)
new process for each request ? not very efficient
but easy to learn, robust (no state)
support from just about any programming language
(C, Perl, Tcl, Python, VisualBasic, ...)
Adapt cgi model to SIP ? sip-cgi
RFC 3050

68
sip-cgi examples

Block _at_vinylsiding.com
if (defined ENVSIP_FROM ENVSIP_FROM
"sip_at_vinylsiding.com")
print "SIP/2.0 600 I can't talk right
now\n\n"
Make calls from boss urgent
if (defined ENVSIP_FROM ENVSIP_FROM
/sipboss_at_mycompany.com/)
foreach reg (get_regs())
print "CGI-PROXY-REQUEST reg SIP/2.0\n"
print "Priority urgent\n\n"

69
Call Processing Language (CPL)

XML-based language for processing requests
intentionally restricted to branching and
subroutines
no variables (may change), no loops
thus, easily represented graphically
and most bugs can be detected statically
termination assured
mostly used for SIP, but protocol-independent
integrates notion of calendaring (time ranges)
structured tree describing actions performed on
call setup event
top-level events incoming and outgoing

70
CPL

Location set stored as implicit global variable
operations can add, filter and delete entries
Switches
address
language
time, using CALSCH notation (e.g., exported from
Outlook)
priority
Proxy node proxies request and then branches on
response (busy, redirection, noanswer, ...)
Reject and redirect perform corresponding
protocol actions
Supports abstract logging and email operation

71
CPL example
72
CPL example

lt?xml version"1.0" ?gt
lt!DOCTYPE call SYSTEM "cpl.dtd"gt
ltcplgt
ltincominggt
ltlookup source"http//www.example.com/cgi-bin
/locate.cgi?userjones"
timeout"8"gt
ltsuccessgt
ltproxy /gt
lt/successgt
ltfailuregt
ltmail url"mailtojones_at_example.comSubjec
tlookup20failed" /gt
lt/failuregt
lt/lookupgt
lt/incominggt
lt/cplgt

73
CPL example anonymous call screening

ltcplgt
ltincominggt
ltaddress-switch field"origin" subfield"user"gt
ltaddress is"anonymous"gt
ltreject status"reject"
reason"I don't accept anonymous calls" /gt
lt/addressgt
lt/address-switchgt
lt/incominggt
lt/cplgt

74
Service creation a comparison
API servlets sip-cgi CPL
language-independent no Java only yes own
secure no mostly can be yes
end user service creation no yes power users yes
GUI tools no no no yes
Multimedia some yes yes yes
call creation yes no no no
75
Service creation for presence services
(work-in-progress)

Accept or deny subscriptions
Shape presence notifications
different level of detail for family, friends and
colleagues
particularly important for geo data
Subscriber can filter detail
primarily, wireless bandwidth constraints
rate limit notifications
XPath?
Mostly, condition/reaction ? CPL can be extended
to most of these functions

76
Pushing context-sensitive data to users

User with mobile device should get location
information when entering city, campus or
building
flight and gate information
maps and directions
local weather forecast
special advisories (choose security checkpoint
2)
Often does not require knowing user
but interface with (e.g.) calendar
Example Columbia implementation
OBEX data exchange over BlueTooth
PDA pushes current appointment or event name
base station delivers directions and map

77
Summary ubiquitous computing using SIP

SIP auxiliary protocols supports many of the
core requirements for ubiquitous computing and
communications
mobility modalities terminal, user, session,
service
service negotiation for devices with different
capabilities
automatic configuration and discovery
with SLP or similar
event notification and triggered actions
automatic actions event filtering, CPL, LESS
(for end system services)
SIP offers a loosely-coupled approach (cf. Jini
or object models)
Also need data push functionality
Avoid tendency to assume SIP users are human
want to interconnect different components and
devices
SIP device configuration needs automation, rather
than screen-scraping

78
Network reliability and QoS measurements

Henning Schulzrinne
Columbia University, New York
University of Cincinnati
March 2003

79
Assessment of VoIP Service Availability

Wenyu Jiang
Henning Schulzrinne
IRT Lab, Dept. of Computer Science
Columbia University

80
Overview

(on-going work, preliminary results, still
looking for measurement sites, )
Service availability
Measurement setup
Measurement results
call success probability
overall network loss
network outages
outage induced call abortion probability

81
Service availability

Users do not care about QoS
at least not about packet loss, jitter, delay
FEC and PLC can deal with losses up to 5-8
rather, its service availability ? how likely is
it that I can place a call and not get
interrupted?
availability MTBF / (MTBF MTTR)
MTBF mean time between failures
MTTR mean time to repair
availability successful calls / first call
attempts
equipment availability 99.999 (5 nines) ? 5
minutes/year
ATT 99.98 availability (1997)
IP frame relay SLA 99.9
UK mobile phone survey 97.1-98.8

82
Availability PSTN metrics

PSTN metrics (Worldbank study)
fault rate
should be less than 0.2 per main line
fault clearance ( MTTR)
next business day
call completion rate
during network busy hour
varies from about 60 - 75
dial tone delay

83
Example PSTN statistics
Source Worldbank
84
Measurement setup
Node name Location Connectivity Network
columbia Columbia University, NY gt OC3 I2
wustl Washington U., St. Louis I2
unm Univ. of New Mexico I2
epfl EPFL, Lausanne, CH I2
hut Helsinki University of Technology I2
rr NYC cable modem ISP
rrqueens Queens, NY cable modem ISP
njcable New Jersey cable modem ISP
newport New Jersey ADSL ISP
sanjose San Jose, California cable modem ISP
suna Kitakyushu, Japan 3 Mb/s ISP
sh Shanghai, China cable modem ISP
Shanghaihome Shanghai, China cable modem ISP
Shanghaioffice Shanghai, China ADSL ISP
85
Measurement setup

Active measurements
call duration 3 or 7 minutes
UDP packets
36 bytes alternating with 72 bytes (FEC)
40 ms spacing
September 10 to December 6, 2002
13,500 call hours

86
Call success probability

62,027 calls succeeded, 292 failed ? 99.53
availability
roughly constant across I2, I2, commercial ISPs

All 99.53
Internet2 99.52
Internet2 99.56
Commercial 99.51
Domestic (US) 99.45
International 99.58
Domestic commercial 99.39
International commercial 99.59
87
Overall network loss

PSTN once connected, call usually of good
quality
exception mobile phones
compute periods of time below loss threshold
5 causes degradation for many codecs
others acceptable till 20

loss 0 5 10 20
All 82.3 97.48 99.16 99.75
ISP 78.6 96.72 99.04 99.74
I2 97.7 99.67 99.77 99.79
I2 86.8 98.41 99.32 99.76
US 83.6 96.95 99.27 99.79
Int. 81.7 97.73 99.11 99.73
US ISP 73.6 95.03 98.92 99.79
Int. ISP 81.2 97.60 99.10 99.71
88
Network Outages

sustained packet losses
arbitrarily defined at 8 packets
far beyond any recoverable loss (FEC,
interpolation)
23 outages
make up significant part of 0.25 unavailability
symmetric A?B ?? B?A?
spatially correlated A?B ? ? A?X?
not correlated across networks (e.g., I2 and
commercial)

89
Network outages
90
Network outages
no. of outages symmetric duration (mean) duration (median) total (all, hm) outages gt 1000 packets
all 10,753 30 145 25 1720 1058
I2 819 14.5 360 25 317 233
I2 2,708 10 259 26 747 537
ISP 8,045 37 107 24 933 458
US 1,777 18 269 20 518 353
Int. 8,976 33 121 26 1202 642
91
Outage-induced call abortion proability

Long interruption ? user likely to abandon call
from E.855 survey Pholding e-t/17.26 (t in
seconds)
? half the users will abandon call after 12s
2,566 have at least one outage
946 of 2,566 expected to be dropped ? 1.53 of
all calls

all 1.53
I2 1.16
I2 1.15
ISP 1.82
US 0.99
Int. 1.78
US ISP 0.86
Int. ISP 2.30
92
Conclusion

Availability in space is (mostly) solved ?
availability in time restricts usability for new
applications
initial investigation into service availability
for VoIP
need to define metrics for, say, web access
unify packet loss and no Internet dial tone
far less than 5 nines
working on identifying fault sources and
locations
looking for additional measurement sites

93
Multimodal Wireless Networking From Message
Forwarding to Infrastructure Networks

Henning Schulzrinne
joint work with
Maria Papadopouli and Stelios Sidiroglou
Computer Science Department
Columbia University
http//www.cs.columbia.edu/IRT
hgs_at_cs.columbia.edu

94
Outline

Introduction
A taxonomy of wireless networks
Motivation
Overview of 7DS
Performance analysis on 7DS
Conclusions
Future work

95
Multimodal networking

"The term multimodal transport is often used
loosely and interchangeably with the term
intermodal transport. Both refer to the transport
of goods through several modes of transport from
origin to destination." (UN)
goods packaged in containers ? packets and
messages
Networking ? combine different modes of data
transport that maximize efficiency

96
Multimodal networking

Speed, cost and ubiquity are the core variables
cf. pipelines, ships, planes, trucks
Traditional assumption of value of immediacy from
PSTN ? demise of Iridium

97
Access modalities
delay
high low
high 7DS 802.11 hotspots
low satellite SMS? voice (2G, 2.5G)
bandwidth (peak)
98
Cost of networking
Modality mode speed /MB ( 1 minute of 64 kb/s videoconferencing or 1/3 MP3)
OC-3 P 155 Mb/s 0.0013
Australian DSL (512/128 kb/s) P 512/128 kb/s 0.018
GSM voice C 8 kb/s 0.66-1.70
HSCSD C 20 kb/s 2.06
GPRS P 25 kb/s 4-10
Iridium C 10 kb/s 20
SMS (160 chars/message) P ? 62.50
Motient (BlackBerry) P 8 kb/s 133
99
Wireless WAN access

Spectrum is very expensive

Location what cost
UK 3G 590/person
Germany 3G 558/person
Italy 3G 200/person
New York Verizon (20MHz) 220/customer

3G bandwidth is very low (around 60 kb/s)

100
Limitations of 802.11

Good for hotspots, difficult for complete
coverage
Manhattan 60 km2 ? 6,000 base stations (not
counting vertical)
With 600,000 Manhattan households, 1 of
households would have to install access points
Almost no coverage outside of large coastal cities

101
Mobile data access

Hoarding grab data before moving
802.11, 3G, BlueTooth wireless as last-hop
access technology
Ad-hoc networks
Wireless nodes forward to each other
Routing protocol determines current path
Requires connected network, some stability
Mobility harmful (disrupts network)
7DS networks
No contiguous connectivity
Temporary clusters of nodes
Mobility helpful (propagates information)

102
A family of access points
103
Limitations of infostations wireless WAN

Require communication infrastructure
not available field operation missions,
tunnels, subway
Emergency
Overloaded
Expensive
Wireless WAN access with low bit rates high
delays

104
Our Approach 7DS

7DS Seven Degrees of Separation
Increase data availability by enabling devices to
share resources
Information sharing
Message relaying
Bandwidth sharing
Self-organizing
No infrastructure
Exploit host mobility

105
Examples of services using 7DS
news
WAN
events in campus, pictures
where is the closest Internet café ?
pictures, measurements
service location queries
schedule info
autonomous cache
106
Information sharing with 7DS
cache miss
Host C
WLAN
cache hit
data
Host B
Host A
107
Simulation environment
pause time 50 s mobile user speed 0 .. 1.5
m/s host density 5 .. 25 hosts/km2 wireless
coverage 230 m (H), 115 m (M), 57.5 m
(L) ns-2 with CMU mobility, wireless
extension randway model
querier
wireless coverage
dataholder
randway model
108
Simulation environment
pause time 50 s mobile user speed 0 .. 1.5
m/s host density 5 .. 25 hosts/km2 wireless
coverage 230 m (H), 115 m (M), 57.5 m
(L) ns-2 with CMU mobility, wireless
extension
querier
wireless coverage
1m/s
pause
mobile host
data holder
109
Simulation environment
pause time 50 s mobile user speed 0 .. 1.5
m/s host density 5 .. 25 hosts/km2 wireless
coverage 230 m (H), 115 m (M), 57.5 m
(L) ns-2 with CMU mobility, wireless
extension
wireless coverage
v1
110
Dataholders () after 25 min
high transmission power
P2P
Mobile Info Server
Fixed Info Server
2
111
Average delay (s) vs. dataholders ()
Fixed Info Server
one server in 2x2 high transmission power
4 servers in 2x2 medium transmission power
112
Average Delay (s) vs Dataholders ()Peer-to-Peer
schemes
high transmission power
medium transmission power
113
Fixed Info Serversimulation and analytical
results
high transmission power
Probability a host will acquire data by time t
follows 1-e-a?t
114
Message relaying with 7DS
WAN
Gateway
WLAN
Message relaying
Host B
Host A
115
Message relaying