ubiquitous computing

Reality Mining

Alex Soojung-Kim Pang — Mon, 03 Mar 2008 12:24:12 -0800

Description

Technology Review declares reality mining one of its top 10 ideas for 2008.

Every time you use your cell phone, you leave behind a few bits of information. The phone pings the nearest cell-phone towers, revealing its location. Your service provider records the duration of your call and the number dialed.

Some people are nervous about trailing digital bread crumbs behind them. Sandy Pentland, however, revels in it. In fact, the MIT professor of media arts and sciences would like to see phones collect even more information about their users, recording everything from their physical activity to their conversational cadences. With the aid of some algorithms, he posits, that information could help us identify things to do or new people to meet. It could also make devices easier to use--for instance, by automatically determining security settings. More significant, cell-phone data could shed light on workplace dynamics and on the well-being of communities. It could even help project the course of disease outbreaks and provide clues about individuals' health. Pentland, who has been sifting data gleaned from mobile devices for a decade, calls the practice "reality mining."

Why does this matter?

Personal reality mining infers human relationships and behavior by applying data-mining algorithms to information collected by cell-phone sensors that can measure location, physical activity, and more.... Cell phones are now sophisticated enough to collect and analyze data on personal behavior, and researchers are developing techniques that allow them to effectively sort through such information.

Impact: Models generated by analyzing data from both individuals and groups could enable automated security settings, smart personal assistants, and monitoring of personal and community health.

Context:

Source

http://www.technologyreview.com/read_article.aspx?ch=specialsections&sc=emerging08&id=20247&a=

Geospatial technology blurs the boundary between cyberspace and urban space to form geocomputable cities

Paul Torrens — Thu, 10 Jan 2008 21:21:06 -0800

Description

The boundary between computing infrastructure and urban infrastructure were blurred to a fuzzy line some time ago and much has been written (and speculated) about on the ramifications of their consociation across a spectrum of topics, from sociology and public policy, to cyborgs and robotic management [1, 2, 3, 4]. Somewhere along the way to the fusion of the computational and the urban, cities became geocomputable spaces.

A number of catalyzing factors are, perhaps, responsible. First, software and computing became increasingly relevant in the management and production of space [5], across the board. Urban utilities are now monitored and managed as large-scale Geographic Information Systems of sensor networks and automated notification systems.

Second, cities and the throngs of people, vehicles, and things that pulse through them have become ambient physical and social infrastructure for large-scale distributed communications networks: digitally interactive crowds with hand-held devices, ubiquitous Wi-Fi signals leaking into the airwaves, and a spaghetti-knot of fiber sequestered in the urban fabric.

Together, these have provided the network-cloud for massively distributed information exchange and computation.

Fourth, digital positioning systems became important in cities, guiding fleets of bike messengers and mail trucks to their destinations with optimal locational accuracy; then, they became ubiquitous, public, and really cheap.

Fifth, near-field and locative technologies based around RFID readers and tags have become ridiculously cost-effective, to the point where individual stores can set up their own geo-grid for automated asset tracking, monitoring, and management. (The navi-wagon shopping cart is just one of many examples.)

Sixth, pattern recognition concentrated on spatial structures of, and spatial compositions in, the urban fabric became useful across applications, from monitoring cars and their licenses remotely in downtown congestion pricing schemes, to law enforcement and policing.

Seventh, intelligent transport systems with strong geospatial components enjoyed a surge in their development and deployment in cities, within roads and across transit systems.

Your location in cityscapes, and your geography in socio-technical urban networks, will become a commodity
Business models fashioned around location-based services have blossomed in very recent years, thanks in large part to a drop in the cost of integrating Global Positioning Systems (GPS) with mobile devices (cell-phones, handheld gaming platforms, personal display assistants, digital cameras, and so on). Concurrently, alternative positioning technology and algorithms based on triangulation of cell-phone and Wi-Fi signals with base stations and access points have evolved to the point where the positional accuracy they produce is useful for consumer mapping. Knowing where you are in a cityscape--and its mirror world in cyberspace--and, particularly, what is around you, will continue to become a commodity that consumers will pay for. At the same time, maps will continue to evolve as the new portal between meatspace and cyberspace, particularly for urban activities, services, and markets, with many groups jostling for position in this new emerging commodity-scape, where commercial interests can pay for brand-name territory. Undoubtedly, there is keen interest in harvesting users’ place-based search and queries to train a new generation of geospatial AI for location-based services. What remains to be seen is whether this arena will become dominated by traditional geospatial technology providers (the potential for Garmin’s nuviphone to erode iPhone market share because of superior positioning technology is an early example [6]) or existing cyberspace behemoths (Intel and Microsoft both have long-standing R&D investment in alternative positioning technologies, for example [7,8]).

The potential for function creep
The emerging glut of technologies used to geoprocess and geocompute in urban areas is so massive that it is difficult to keep track, manage, and regulate them. This latter point is particularly salient with respect to the potential emergence of function creep in the use and application of these technologies and the vast stores of data they will produce. Geospatial technologies of this kind create a bridge between cyberspace and cyberplace and users’ Online data-shadows can be potentially traced to the real-world with greater ease. This creates new emerging opportunities for marketing, advertising, and commercial data-mining, and as with most emerging technologies, it creates privacy concerns. Already, geodemographics for marketing have begun to farm these data-sets, and algorithms for creating privacy masks and filters are emerging. How these data and services creep across interoperability boundaries to add value to related (or unrelated) services will shape the future development and application of these technologies.

The potential for things to go wrong
What happens when geocomputable cities are hacked, crash, or succumb to malware or viruses? Thus far, we have been spared any serious locative-based mechanical, software, or system failures. As geocomputable cities begin to play host to intelligent highways and robotic drivers, thorny issues regarding positional accuracy and spatial ontologies will likely surface. These are not issues that are easily solved with version 2.0 iterations to existing technologies and they pose grand challenges for future research and development.

Geospatial technology will expand the Digital Divide
Many of these technologies already divide and partition urban spaces based on place-time tuples that authenticate some people as valid participants in particular buildings, places, and spaces at particular times (at the simplest level through RFID-embedded card access, for example). The potential for socio-technical spatial polarization among the geodigital valids and invalids is profound [9]. As geospatial technologies develop in sophistication and their application-sets grow and expand, newly segregated divides may well emerge.

References
[1] Mitchell, W. J. (1995). City of Bits: Space, Place, and the Infobahn. Cambridge, MA: The MIT Press.

[2] Batty, M. (1995). “The computable city”. Paper read at Fourth International Conference on Computers in Urban Planning and Urban Management, July 11th - 14th, 1995, at Melbourne.

[3] McCullough, M. (2004). Digital Ground: Architecture, Pervasive Computing, and Environmental Knowing. Cambridge, MA: The MIT Press.

[4] Rheingold, H. (2002). Smart Mobs: The Next Social Revolution. London: Perseus Books.

[5] Graham, S. (2005). “Software-sorted geographies”. Progress in Human Geography 29 (5):562-580.

[6] Jonson, Joel (2008). "Nuviphone: Garmin Announces First Credible iPhone Competitor, boingboing.net, January 31, 2008.

[7] Knies, Rob (2005). "Using Wi-Fi to make your device find where you are", Microsoft Research News and Highlights.

[8] Cheng, Yu-Chung; Chawathe, Yatin; Krumm, John (2003). "Accuracy characterization for metropolitan-scale Wi-Fi localization". Intel Research IRS-TR-05-003.

[9] Dobson, J., and P. Fisher. (2003). “Geoslavery”. IEEE Technology and Society Magazine 22 (1):47-52.

Signals

Software-sorted geographies

Geoslavery

The Computable City paper

RFID Embedded in Physical Objects

Alex Soojung-Kim Pang — Tue, 23 Oct 2007 11:10:30 -0700

Description

Embedding RFID computer chips in physical objects will allow these objects to be identified and tracked by ubiquitous sensors.

Signals

Computing on the Human Platform

Alex Soojung-Kim Pang — Tue, 23 Oct 2007 11:10:30 -0700

Description

Interaction between personal electronic products, mediated by human skin, may lead to new, and increasingly invasive, applications.

Personal electronic products can communicate with each other and with external networks using human skin as a medium. The convergence of electronic implants, wearables, and personal area networks (both wireless and 'wired' using the skin as a medium) could coincide with a shift from therapeutic body modification for disabilities to personal augmentation for healthy individuals. For example, while optoelectric implants can restore lost vision, they could also be used to give people the ability to see outside the visible spectrum, infrared and so forth.
Significant resistance to implantable devices may persist due to social, moral, ethical, and religious objections. Even Bill Gates, speaking about chip implants at a Microsoft seminar in July 2005, said,

'One of the guys that works at Microsoft always says to me "I'm ready, plug me in." I don't feel quite the same way. I'm happy to have the computer over there and I'm over here.'

Still, even people who are averse to the idea of implants will probably be able to achieve many of the same benefits through externally worn devices. While implants are likely to be widely available in 20 years, the majority of human computational extensions may be more like an exoskeleton.

Korea may exhibit the greatest uptake of these new technologies. There, high broadband use plus the world's highest rate of plastic surgery provide the medical technology infrastructure and the demand necessary to drive development."

This will be enabled by:

Increasing spread of the Bluetooth and UWB personal area networking protocols
Development of subdermal lithium-ion batteries that can be recharged through magnetic induction

Early indicators include:

"Issuing of US Patent 6,754,472 to Microsoft in June 2004 for a 'method and apparatus for transmitting power and data using the human body'
Worldwide electromedical implant market of $10 billion in 2004"

What to watch:

Electronic implants to augment organs of perception become widely available.