Guest Editorial
At some point in the future, how far out
we do not exactly know, wireless access to the Internet will outstrip all other
forms of access bringing the freedom of mobility to the way we access the web,
communicate with each other, and conduct business. In short, the Internet is
going mobile and wireless, perhaps quite soon.
A number of diverse technologies are
leading the charge, including, 3G cellular networks based on CDMA technology, a
wide variety of what is deemed 2.5G cellular technologies (e.g., EDGE, GPRS and HDR),
and IEEE 802.11 wireless local area networks (WLANs). Wireless ISPs will offer
a number of these technologies to mobile users. In some case, handsets will
come with software radios that simultaneously support multiple access
technologies on-the-fly; for example, IEEE 802.11 for high-bandwidth access in
urban areas and GPRS for wide area access in rural areas.
Each
technology has its pros and cons. First and second generation cellular
systems offer wide area low bandwidth voice services based on analog and
digital technology, respectively. The
3G cellular systems are designed to carry voice, video and data
simultaneously, and
offer data rates of 144 Kbps for fast-moving mobile users in vehicles, 384 Kbps
for slower moving pedestrian users, and 2 Mbps from fixed locations. Note that
all users within a cell share these data rates. The 3G networks offer higher
capacity and increased spectral efficiency but retain a circuit-switched,
hierarchical architecture. In contrast, WLAN offers even
higher bandwidth and is considered IP friendly because it offers a link layer
that is very similar to wired Ethernet. However, in comparison to 3G networks,
WLAN only operates within the local area, only supports best effort services,
and uses shared unlicensed spectrum where few quality assurances can be
provided to users.
Recently,
there has been a considerable amount of press on the slow rollout of 3G.
However, there are some signs for optimism. Japan’s NTT DoCoMo
started offering 3G services in October 2001 in the Tokyo area. This
came after the initial postponement of the rollout of 3G services by providers
in Japan and Europe. Since May 2001, 5,000 residents in the Tokyo area have
been using new 3G phones that offer improved i-mode service and real-time videoconferencing. The initial video offering uses a
64 Kbps circuit that carries video and audio combined. One of the guest editors had the opportunity
to use a trial handset to set up a video call to a colleague in a taxi while
traveling through Tokyo. The real-time video call, which used MPEG4 technology,
presented mixed service quality but the experience of setting up the call
between two taxis was exciting. I-mode currently has 29 million subscribers in
Japan and DoCoMo hopes to keep that figure rising with the new service
offerings. The DoCoMo radio access network is based on WCDMA and the core
network on ATM switching.
Many
carriers in the US and Europe will be keenly watching what is happening in
Tokyo. Wireless providers in the United States are eager to
follow suit but are rolling out service in phases with emphasis on 2.5G
technologies such as GPRS, which provides an always-on connection to the
Internet that allows users to toggle between surfing the web, a phone call, or
text messaging without losing the connection.
Carriers in Europe, which have invested more than $100 billion to buy 3G
radio spectrum licenses and will need to invest another $100 billion for the
build-out of the 3G networks, will be keeping a close watch on DoCoMo’s
successes and failures.
The
vast majority of WLAN deployed today is based on IEEE 802.11b operating at 2.4
Ghz and offering data rates up to 11 Mbps. Recently, a number of companies have
demonstrated IEEE 802.11a, which operates in the 5Ghz band and offers data rates up to 54 Mbps. In fact, Atheros
Communications supports a “turbo-networking” mode that delivers 108 Mbps,
roughly equivalent to Fast Ethernet.
The cost of the 3G spectrum and the build-out of the 3G networks have
been so prohibitive that many operators have been pushed to the brink of
bankruptcy. As a result, many small operators in Europe are sharing the cost of
the build-out by sharing core and radio access network infrastructure. In
contrast, WLAN infrastructure operates
in unlicensed frequency bands and is very cheap in comparison to cellular
equipment. Cheap,
because WLAN base-station transceivers are priced at less than $1,000, and
transceiver cards are around $100 or come built into computers. Public wireless LANs can handle large volumes of data
at significantly lower costs compared to leading 3G technologies. The cost benefit
and bandwidth differential offered by WLAN technology makes it a disruptive technology
as the cellular operators migrate from 2G to 3G.
Disruptive technologies are characterized as being cheaper
and of lower performance than sustaining technologies (e.g., 2.5G or 3G
solutions). Most public wireless
networks and enterprise networks use WLAN, not because it is more secure,
robust or spectrally efficient, but simply because it is cheap, offers high
bandwidth, makes networks easy to build and configure, and, importantly, it
works. Typically, customers are not
initially satisfied with the performance offered by disruptive technologies
when they are first introduced. For WLAN to compete in the marketplace with
2.5G and 3G solutions, public WLAN operators would need to be capable of
building metropolitan area networks that provided suitable support for
voice-over-IP thereby enabling voice communications. Sharing unlicensed
spectrum means that wireless ISPs cannot build managed networks where services
are tightly controlled, in isolation from other operators, as a means of
assuring performance. Historically,
however, disruptive technologies have tended to resolve such performance
problems as they mature and begin to capture market share.
Examples of wireless extensions to
Internet are all around us today. Here in New York City many companies,
university campuses, coffee shops and stores offer wireless access to the web
using WLAN technology. Columbia University, for example, provides students and
faculty wireless access to the web as they move around campus. Companies such as MobiStar and Waypoint
provide wireless connections at hotels, airports and cafes. Around Manhattan,
Starbucks coffee shops offer wireless access to the Internet. At the grassroots level, community groups
are putting up wireless antennas around the New York City area and in other
cities offering free access to Internet.
Some predict that these “freenets”, which have a feel reminiscent to
Napster, will ultimately succumb to a sustained corporate challenge or new
wireless ISPs that offer cheap services across dense urban areas. The road to success for such
fledgling operators may be littered with a number of business, regulatory and
performance obstacles.
There
are a number of companies, standards bodies, and industrial fora vying to
define future wireless extensions to the Internet. The end result is that
operators are faced with a large and confusing array of choices on how best to
build next generation mobile networks. 3G systems offer support for seamless
mobility, paging, and service quality but are built on complex and costly
connection-oriented networking infrastructure that lacks the inherent
flexibility, scalability, and cost effectiveness found in IP networks. In contrast, Mobile IP represents a simple
and scalable global mobility solution but lacks support for fast handoff
control, real-time location tracking, and authentication and distributed policy
management found in cellular networks today.
There has also been considerable interest in new emerging wireless technologies
such as personal area networks, mobile ad hoc networks and sensor networks. How
these technologies interwork with the global Internet is an active area of
research.
A number of micro-mobility protocols
(e.g., Cellular IP, Hawaii, Hierarchical
Mobile IP) and fast handoff schemes have been discussed in the IETF Mobile IP
Working Group that address some of these performance and scalability issues.
These protocols are designed for environments where mobile hosts change their
point of attachment to the network so frequently that the basic Mobile IP
protocol tunneling mechanism introduces network overhead in terms of increased
delay, packet loss and signaling. For example, many real-time wireless
applications (e.g., voice-over-IP) would experience noticeable degradation of
service with frequent handoff. Establishment of new tunnels can introduce
additional delays in the handoff process, causing packet loss and delayed
delivery of data to applications. This delay is inherent in the round-trip
incurred by Mobile IP as the registration request is sent to the home agent and
the response sent back to the foreign agent. Micro-mobility protocols aim to
handle local movement (e.g., within a domain) of mobile hosts without
interaction with the Mobile IP enabled Internet. This has the benefit of
reducing delay and packet loss during handoff and eliminating registration
between mobile hosts and possibly distant home agents when mobile hosts remain
inside their local coverage areas. Eliminating registration in this manner
reduces the signaling load experienced by the network in support of
mobility.
As the numbers of wireless users grow so
will the signaling overhead associated with mobility management. In cellular
networks registration and paging techniques are used to minimize the signaling
overhead and optimize mobility management performance. Currently, Mobile IP
supports registration but not paging.
An important characteristic of micro-mobility protocols is their ability
to reduce the signaling overhead related to frequent mobile migrations taking
into account a mobile host's operational mode (i.e., active or idle). When
wireless access to Internet becomes the norm then Mobile IP will have to
provide efficient and scalable location tracking in support of idle users, and
IP paging in support of active communications. Support for “passive
connectivity” to the wireless Internet balances a number of important design
considerations. For example, only keeping the approximate location information
of idle users requires significantly less signaling and thus reduces the load
over the air interface and in the network. Reducing signaling over the air
interfaces in this manner also has the benefit of preserving the power reserves
of mobile hosts. Currently, the IETF Seamoby Working Group is tasked with
developing an IP paging protocol.
The
papers in this special issue address a number of the issues and challenges
discussed above. We received a total of 32 excellent submissions for this
special issue -- a much greater response to our call for papers than we
expected. The papers came from different regions around the world and addressed
many different aspects of research. Each paper was reviewed by three or more
experts, who evaluated the technical content and suitability of the paper for
publication in this special issue. As guest editors of the special issue we had
the very difficult job of selecting only six papers from those submitted.
Several deserving papers could not be accommodated in this special issue
because of space. We hope to see those papers appear later in ACM SIGCOMM
Computer Communication Review.
The first three papers in this special
issue address a number of enhancements to Mobile IP and cellular networks to
provide for better support for fast handoff and context transfer, wireless
Internet telephony, and IP paging. The final three papers deal with the
emerging technologies of personal area networks, mobile ad hoc networks and
sensor networks.
In
the first paper, Jonathan Lennox, Kazutaka Murakami, Mehmet Karaul and Thomas
F. La Porta, Lucent Technologies, discuss internetworking Internet telephony
and wireless telecommunications networks. The authors propose a number of
schemes to directly interconnect the 3G UMTS and SIP Internet telephony
systems.
The
next paper by Rajeev Koodli and Charles E. Perkins, Nokia, deals with seamless
handoff and context relocation in mobile networks. Context transfer refers to state information
(e.g., QOS state) associated with a particular service (e.g., VoIP) that needs
to be re-established with mobility. The
authors show that fast handoff with context transfer at the network layer can
support uninterrupted voice-over-IP services.
The
paper by Pars Mutaf and Claude Castelluccia, INRIA, proposes adaptive per-host
IP paging. The authors observe that many of the existing IP paging proposals
found in the literature promote the use of static or manually configured paging
areas. The authors argue that there is a need for dynamic and adaptive paging
area management that takes into account host mobility and traffic patterns in
the network.
Robin Kravets, Casey Carter and Luiz Magalhaes, University of Illinois,
Urbana-Champaign, discuss cooperative approaches to user mobility. The authors
propose the necessary networking functionality that allows groups of mobile
devices (e.g., a set of devices that collectively comprise a personal area
network) to interact and be seamlessly integrated into the Internet.
In the next paper, Jyoti Raju and J.J. Garcia-Luna-Aceves UC Santa Cruz, present a new
mobile ad hoc network routing protocol called source tracing and compare it
with dynamic source routing (DSR). Both
on-demand and table-driven implementations are considered.
The final paper in this special issue, by
Samir Goel and Tomasz Imielinski, Rutgers University, considers the problem of
monitoring data in large sensor networks. The authors propose a
prediction-based monitoring scheme that can be visualized by leveraging
concepts and techniques found in image processing.
There are many other
technical challenges before Internet goes truly wireless and mobile. For
example, there is a need to minimize the impact of mobility on TCP performance,
resolve security issues over-the-air, and further study how best content can be
pushed toward mobile users. Finally, in
the wake of the recent attack in New York City, we anticipate new advances in
rapidly deployable wireless infrastructure, self-configuring networks, and
sensor networks - collectively forming disaster relief networks.
As
guest editors it has been a great pleasure to put together this issue. We would
like to thank the authors for their contributions and the reviewers for their
time, energy, and comments that helped shape this special issue. We hope you enjoy it as much as we do.
Biographies
Andrew T. Campbell is an Associate Professor in the Department of Electrical Engineering,
and a member of the COMET Group and the
Columbia Networking Research Center, Columbia
University, New York. His areas of interest encompass mobile networking,
programmable networks, and QOS research. Andrew currently serves as technical program
co-chair for the 8th ACM International Conference on Mobile Computing and
Networking (ACM MobiCom 2002), and technical chair of the special track on
networking technologies, services and protocols for IFIP Networking 2002. He received his Ph.D. in Computer Science in 1996 and the NSF CAREER
Award for his research in programmable mobile networking in 1999.
Mischa Schwartz is Charles Batchelor Professor Emeritus of Electrical Engineering at Columbia University. He is the author and co-author of nine books in communication systems, computer and telecommunication networks, and signal processing. His current research focuses on wireless networks. He is a member of the National Academy of Engineering. He is a Life Fellow and former Director of the IEEE, past President of the IEEE Communications Society, and past Chairman of the IEEE Group on Information Theory. He was the 1983 recipient of the IEEE Education Medal, received the Cooper Union Gano Dunn Award in 1986 for outstanding achievement in Science and Technology, the IEEE Communication Society’s Edwin Armstrong award in 1994 for achievement in Communications Technology, and the City of New York Mayor’s Award for Excellence in Technology in 1995. He received the Eta Kappa Nu Eminent Member Award in 2000.