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Mobile and Pervasive Computing - 1 (TE-8019) Introductory Lecture

Mobile and Pervasive Computing - 1 (TE-8019) Introductory Lecture. Presented by: Dr. Adeel Akram University of Engineering and Technology, Taxila , Pakistan http://web.uettaxila.edu.pk/CMS/SP2014/teMPCms. What is Ubiquitous Computing (ubicomp).

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Mobile and Pervasive Computing - 1 (TE-8019) Introductory Lecture

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  1. Mobile and Pervasive Computing - 1 (TE-8019)Introductory Lecture Presented by: Dr. Adeel Akram University of Engineering and Technology, Taxila, Pakistan http://web.uettaxila.edu.pk/CMS/SP2014/teMPCms

  2. What is Ubiquitous Computing (ubicomp) • Ubicomp is a post-desktop model of human computer interaction in which information processing has been thoroughly integrated into everyday objects and activities. • Integrate computers seamlessly into the world – invisible, everywhere computing. – Often called pervasive/invisible computing. • Computers are mostly not invisible , they dominate interaction with them. • Ubicomp is about making computers invisible.

  3. Ubiquitous computing = mobile computing + intelligent environment. Technology View • Computers everywhere – embedded into fridges, washing machines, door locks, cars, furniture. • Intelligent environment. • Mobile portable computing devices • Wireless communication– seamless mobile/fixed. User View • Invisible – implicit interaction with your environment. • Augmenting human abilities in context of tasks

  4. Ubicomp vs. Virtual Reality • Should we live in virtual computing world? Or should computing come out and live in our physical world? • VR is about simulating physical world & putting people inside virtual computing world. (Limited applications & activities.). • Ubicomp is about bringing computing to people’s physical world, integrating with everyday objects and activities. • Ubiquitous computing is an integration of human factors, computer science, engineering, and social sciences.

  5. Ubiquitous, Mobile, and Nomadic Computing • Nomadic computing: “portable”; no mobility while connected. • Mobile computing: “on-the-go”, e.g., while sitting on a train; possibility of network connections remaining open. • Ubiquitous computing: computing everywhere… OR computers everywhere…most of them invisible

  6. State of Art and The Future of Computing

  7. Section 1: Pervasive Computing • Golden Richard. Fundamentals of Mobile and Pervasive Computing. McGraw-Hill Professional Publishing ; December 2004. (with special emphasis on security issues) • Uwe Hansmann, Lothar Merk, Martin S. Nicklous, T. Stober. (Edt.) Pervasive Computing, 2nd Edition. Springer-Verlag Telos; May 2003. • Jochen Burkhardt, Horst Henn, Stefan Hepper, Klaus Rindtorff and Thomas Schaeck. Pervasive Computing: A New Class of Computing Devices. Addison-Wesley Pub Co; January, 2002. • Uwe Hansmann, Lothar Merk, Martin S. Nicklous, and Thomas Stober. Pervasive Computing Handbook. Springer-Verlag, 2001.

  8. Section 2: Mobile Computing • Reza B'Far. Mobile Computing Principles: Designing and Developing Mobile Applications with UML and XML. Cambridge University Press, 2005. • Evaggelia Pitoura, George Samaras. Data Management for Mobile Computing (Advances in Database Systems). Kluwer Academic Publishers, 2004. • Dharma P. Agrawal and Qing-An Zeng. Introduction to Wireless and Mobile Systems. Brooks/Cole-Thomson Learning, 2003. • Ivan Stojmenovic, Edt. Handbook of Wireless Networks and Mobile Computing. Kluwer Academic Publishers, Boston , February 2002. • Evaggelia Pitoura and George Samaras. Data Management for Mobile Computing. January 1998. • Tomasz Imielinski, Tamasz Imielinski, and Henry F. Korth. Mobile Computing. Kluwer Academic Publishers, Boston , January 1996.

  9. Section 3: Distributed Systems • George Coulouris, Jean Dollimore and Tim Kindberg. Distributed Systems: Concepts and Design, 4th Edition. Addison-Wesley, 2005. • Andrew S. Tanenbaum and Maarten van Steen. Distributed Systems: Principles and Paradigms. Prentice Hall, 2002. • Randy Chow and Theodore Johnson. Distributed Operating Systems and Algorithms. Addison Wesley, 1997. • Kenneth P. Birman. Building Secure and Reliable Network Applications. Manning Publications Co., 1996. • Sape Mullenter (ed.), Distributed Systems, 2nd Edition, ACM Press, 1993.

  10. Papers: Introduction to Mobile and Pervasive Computing • Mark Weiser, "The Computer for the 21st Century," Scientific American, September 1991. (HTML, PDF) • Mark Weiser, "Some Computer Science Issues in Ubiquitous Computing", Communications of the ACM 36(7):75-84, July 1993. (PDF) • M. Satyanarayanan, "Pervasive Computing: Vision and Challenges," IEEE Personal Communications, August 2001. (PDF) • D. Saha, A. Mukherjee, "Pervasive Computing: A Paradigm for the 21th Century," IEEE Computer, March 2003, pp. 25-33. (PDF) • G. H. Forman and J. Zahorjan, "The Challenges of Mobile Computing," IEEE Computer 27(4):38-47, April 1994. (PDF) • J. Barton and T. Kindberg, "The Challenges and Opportunities of Integrating the Physical World and Networked Systems," HP Labs Technical Report, Jan 31, 2001. (PDF) • G. Banavar, J. Beck, E. Gluzberg, J. Munson, J. Sussman, and D. Zukowski, "Challenges: An Application Model for Pervasive Computing," Proc. 6th ACM MobiCom, Boston, MA, Aug 2000. (PDF) • Andrew C. Huang, Benjamin C. Ling and Shankar Ponnekanti, "Pervasive Computing: What is it Good for?" MobiDE, pp. 84-91, 1999. (HTML)

  11. Papers: Context-Aware Computing and Location-Based Services • H. Lieberman and T. Selker, "Out of Context: Computer Systems That Adapt to, and Learn from, Context, IBM System Journal 39(3-4), 2000. (PDF) • G. Chen and D. Kotz, "PA Survey of Context-Aware Mobile Computing Research," Dartmouth College, 2000. (PDF) • M. Korkea-aho, "Context-Aware Applications Survey," Helsinki University of Technology, 2000. (HTML) • Sven Meyer and Andry Rakotonirainy, "A Survey of Research on Context-Aware Homes," 2003. (PDF)

  12. Papers: Sensor Networks • Ian F. Akyildiz, Weilian Su, Yogesh Sankarasubramaniam, and Erdal Cayirci, "A Survey on Sensor Networks", IEEE Communication, 102-114, Aug 2002. (PDF) • Chee-Yee Chong and Srikanta P. Kumar, "Sensor Networks: Evolution, Opportunities, and Challenges," Proceedings of the IEEE 91(8), Aug 2003. (PDF) • Archana Bharathidasan and Vijay Anand Sai Ponduru, "Sensor Networks: An Overview," Technical Report, Dept. of Computer Science, University of California at Davis, 2002. (PDF) • Heinzelman, W.B., Murphy, A.L., Carvalho, H.S. and Perillo, M.A., "Middleware to support sensor network applications," IEEE Network 18:6-14, 2004.(PDF) • Deepak Ganesan, Alberto Cerpa, Yan Yu and Deborah Estrin, "Networking Issues inWireless Sensor Networks," Journal of Parallel and Distributed Computing 64(7):799-814, July 2004.(PDF)

  13. Case Studies • MIT • OXYGEN Project • Carnigie Mellon University • Aura Project • University of Washington • http://ubicomplab.cs.washington.edu/wiki/Projects • University of California, San Diego • Active Campus http://activecampus.ucsd.edu/

  14. Case Studies • Georgia Tech University • Aware Home Research Initiative http://awarehome.imtc.gatech.edu/ • Cyber Desk http://www.cc.gatech.edu/fce/cyberdesk/index.html • Cyber Guide http://www.cc.gatech.edu/fce/cyberguide/index.html • NUCES Fast Karachi • Ubiquitous Computing Research Group http://cruc.khi.nu.edu.pk/ ( http://archive.is/j0tyO )

  15. Seminar Presentations • https://wiki.engr.illinois.edu/display/cs598rhc/Ubiquitous+Computing+WebSites+and+Projects • Students will select their project of interest and give presentation and formal report on them

  16. Text Book • Title: Ubiquitous Computing Fundamentals • Author: John Krumm, PhD • Affiliation: Microsoft Research • Published in: Redmond, Washington, USA • Publisher: Chapman and Hall/CRC • Publication year = 2010 • Editor: John Krumm • ISBN: 978-1-4200-9360-5

  17. Reference Books • Title: Fundamentals of Mobile and Pervasive Computing • Author: Frank Adelstein, Golden Richard III, PhD • ISBN: 0071412379 • Publisher: McGraw-Hill Professional • Publication Year: 2004

  18. History of Ubicomp • Mark Weiser coined the phrase "ubiquitous computing" around 1988, during his tenure as Chief Technologist of the Xerox Palo Alto Research Center (PARC). • Both alone and with PARC Director and Chief Scientist John Seely Brown, Weiser wrote some of the earliest papers on the subject, largely defining it and sketching out its major concerns. • Andy Hopper from Cambridge University UK proposed and demonstrated the concept of "Teleporting" - where applications follow the user wherever he/she moves. • Bill Schilit (now at Google) also did some earlier work in this topic, and participated in the early Mobile Computing workshop held in Santa Cruz in 1996.

  19. History of Ubicomp • Dr. Ken Sakamura of the University of Tokyo, Japan leads the Ubiquitous Networking Laboratory (UNL), Tokyo as well as the T-Engine Forum. • The joint goal of Sakamura's Ubiquitous Networking specification and the T-Engine forum, is to enable any everyday device to broadcast and receive information. • Roy Want, while a researcher and student working under Andy Hopper at Cambridge University, worked on the "Active Badge System", which is an advanced location computing system where personal mobility that is merged with computing.

  20. History of Ubicomp • MIT has also contributed significant research in this field, notably Things That Thinkconsortium at the Media Lab and the CSAIL effort known as Project Oxygen. • Other major contributors include University of Washington's Ubicomp Lab, Georgia Tech's College of Computing, Cornell University's People Aware Computing Lab, NYU's Interactive Telecommunications Program, UC Irvine's Department of Informatics, Microsoft Research, Intel Research.

  21. History of Ubicomp Mark Weiser Father of Ubicomp http://www.ubiq.com/weiser

  22. History of Ubicomp • Ubiquitous computing (ubicomp) is an advanced computing concept where computing is made to appear everywhere and anywhere. • In contrast to desktop computing, ubiquitous computing can occur using any device, in any location, and in any format. • A user interacts with the computer, which can exist in many different forms, including laptop computers, tablets, terminals and phones. • The underlying technologies to support ubiquitous computing include Internet, advanced middleware, operating system, mobile code, sensors, microprocessors, new I/O and user interfaces, networks, mobile protocols, location and positioning and even new materials.

  23. Ubicomp core concepts • At their core, all models of ubiquitous computing share a vision of small, inexpensive, robust networked processing devices, distributed at all scales throughout everyday life and generally turned to distinctly common-place ends. • For example, a domestic ubiquitous computing environment might interconnect lighting and environmental controls with personal biometric monitors woven into clothing so that illumination and heating conditions in a room might be modulated, continuously and imperceptibly. • Another common scenario posits refrigerators "aware" of their suitably tagged contents, able to both plan a variety of menus from the food actually on hand, and warn users of stale or spoiled food.

  24. Ubicomp core concepts • Ubiquitous computing presents challenges across computer science: in systems design and engineering, in systems modelling, and in user interface design. • Contemporary human-computer interaction models, whether command-line, menu-driven, or GUI-based, are inappropriate and inadequate to the ubiquitous case. • This suggests that the "natural" interaction paradigm appropriate to a fully robust ubiquitous computing has yet to emerge - although there is also recognition in the field that in many ways we are already living in an Ubicomp world.

  25. Ubicomp core concepts • Ubiquitous computing may be seen to consist of many layers, each with their own roles, which together form a single system: • Layer 1:task management layer • Monitors user task, context and index • Map user's task to need for the services in the environment • To manage complex dependencies • Layer 2:environment management layer • To monitor a resource and its capabilities • To map service need, user level states of specific capabilities • layer 3:environment layer • To monitor a relevant resource • To manage reliability of the resources

  26. Intelligence • Embedded Computing for enhancing physical objects. • Achieve intelligence through interconnection of physical objects. • Achieve intelligence through location awareness (without AI) For example: Automated call forwarding (context awareness – should know where the person is) lighting control  smart sensor wall - control heating and lighting.

  27. Early work Tabs: • very small – smart badge with user info, calendar, diary, etc. • allow personalized settings to follow a user • Carried around by a person • Hundreds in a room • Remote controllers • Badges • Tags / Labels (RFID) • Locating system (tags as library catalogs) • Animate static physical objects (active calendar, active map)

  28. Current Trends Touch Pads: • Foot-scale Ubicomp devices • A sheet of paper / tablet PC. • Portable computers but not laptop metaphor • Tens in a room • Like scrap papers that can be grabbed and used anywhere, no unique ID.

  29. Currently in use in Academia and Enterprise Boards: • larger display – whiteboard size. • Personalized electronic bulletin boards. • Multiple pens. • Meeting capture. • Lots of bandwidth available because they’re plugged into the wall (LAN Network) • White board with e-chalk Shared white board with remote participants. • Video screen. • Electronic Bookcases

  30. Current Technology • Portable information appliances – laptops, notebooks, and sub-notebooks – hand-held computers – PDAs and smart phones • Wireless communication networks – multiple networks “covering” the globe • Internet: – TCP/IP& de-facto application protocols

  31. Usability • Common user interface for workstation and mobile device applications. • Adaptive information display. • Flexible voice based input-output. • Voice recognition + text to speech conversion. • Gesture recognition. • Intelligent agents

  32. Mobile computing • Mobile computing - wireless transmission. • Uses a computing device. • Many types of mobile computers have been introduced since the 1990s, including the: • Personal Digital Assistant • Enterprise Digital Assistant • Smart phones • UMPC

  33. Mobile computing Vision • Universal connectivity – anywhere, anytime • Accommodate heterogeneity of networks and communicators. • Ubiquitous intelligent environment - embedded computers everywhere • Easy user interaction • Context independent access to services + context dependent information

  34. Issues • How to integrate mobile communicators into complex information infrastructures? • What effect will they have on work and leisure? • Privacy • How to develop and manage adaptable, context-aware software systems? • What support is needed within the network? • Power supplies

  35. Integration of Mobile Systems • Not stand alone devices. Need to interact with complex legacy information systems eg large databases – merging updates, displaying tables etc. • Systems development Requirements specification for adaptable systems Component composition to meet global QoS, security, reliability & performance requirements. • Mobility models Behaviour specification and analysis Modelling context aware systems

  36. Context Aware Computing • It is a powerful and long-lasting, concept in human computer interaction. • Interaction with computation is by explicit acts of communication (e.g. pointing to a menu item), context is implicit (e.g. default setting). • Goalof context-aware computing is to acquire and utilize information about the context of a device to provide services that are appropriate to the particular people, place, time, events, etc. • For example, a cell phone will always vibrate and never beep in a concert, if the system can know the location of the cell phone and the concert schedule

  37. Context Adaptation • A context adaptive system enables the user to maintain a Certain application (in different forms) while roaming between different wireless access technologies, locations, devices and even simultaneously executing everyday tasks like meetings, driving a car etc.

  38. Issues : Context Awareness • Current location Need location detection e.g. GPS or base station Indoors – radio beacon, IR. • User activity Walking, driving a car, running for a bus – how to detect this? • Ambient environment In theatre, alone, in meeting • Local resources or services available Device capabilities • Screen, input, processing power, battery life …. • Current QoS availability – particularly for radio links

  39. Intelligent Environment • An intelligent environment is a location (e.g. home, office, hospital, etc) that is equipped with sensors, actuators and computers that are networked with each other and the internet. • The components are controlled by "intelligent agent" software that knows the preferences of the occupants. • It tailors the environment to suit them. • The occupants can talk to the environment using speech and natural language and the sensors can monitor the environment.

  40. Smart Dust • Autonomous sensing and communication in a cubic millimetre – “dust motes”. • "Smart dust" devices are tiny wireless Micro Electro Mechanical Sensors (MEMS) that can detect everything from light to vibrations. • Sensors for temperature, humidity, light, motion …. with bidirectional radio or laser + battery. • Typical Applications: -- Defence related battlefield sensors, motion detectors etc. -- Inventory control on boxes which communicate with trucks, plane etc. to tell you where they are. -- Product quality monitoring – vibration, humidity, overheating. -- Car component monitoring.

  41. Smart Dust Components

  42. Smart Dust • Smart paint monitors vibrations and detect intruders. • Changes colour to react to temperature, lighting etc. • Intelligent glass can filter sunlight, become opaque no need for curtains. • Smart garments or injectable sensors for people monitoring.

  43. Issues • What means of communication? • Radio • Light based • Batteries would be impractical power source for 100K processors per person. • Solar cells are not suitable for all environments. • Solar cells, fuel cells, body heat power? • Power not speed is the key issue for future processor designs.

  44. Major Challenges Hardware Prototype Issue: • Power consumption: impossible to change batteries to many Ubicomp devices frequently. • Balance of HW/SW feature: display, network, processing, memory, storage capability, multitasking, QoS, etc. • Ease of expansion & modification (integration vs. modular).

  45. Major Challenges Network Issue: • Wireless Media Access (802.11, Bluetooth, Cellular Networks). • Quality of Services (RSVP, etc.). • Ubicomp devices changing network attachment points (Mobile IP).

  46. Major Challenges Application Issue: • “Applications are of course the whole point of ubiquitous computing”. • Locating people (active badges) Automated call forwarding Tracking down people for meeting Watching general activity in a building (feel in touch with surrounding environments) • Shared drawing in virtual meeting Scalability to 5000 peoples (multicast for bandwidth efficiency)

  47. Security • Interactions will be cross multiple organisational boundaries specification, analysis and integration for heterogeneous OS, databases, firewalls, routers. • Everything worth hacking gets hacked. • Need for secure ‘out of the box’ set up that can identify friend or foe - level of trust. • Small communicators, with confidential data, are easily lost or stolen – biometric authentication. • Necessary security technology exists.

  48. Privacy • Location service tracks movement to within metres. • Clearly indicate you are being sensed or recorded + user control to stop recording or control distribution of information. • You are now predictable System can co-relate location, context and behaviour patterns • Do you want employer, colleagues or insurance company to know you carry a medical monitor? • Tension between authentication and anonymity – business want to authenticate you for financial transactions and to provide ‘personalized’ service web sites. • Constant spam of context dependent advertising

  49. Management • Huge, complex systems • Billions of processors • Multiple organisations • Managing physical world, controlling sensors, actuators • Hacker and virus paradise • System propagates false information about individuals or organisation. • Complexity of s/w installation on a workstation or server – how do you cope with billions?

  50. Proposed Management Solution • Intelligent agents, mobile agents, policy. • QoS Management Fat pipes and large storage can convert media streams to short traffic bursts in core network but still needed for wireless links. • Adaptive self-management is the only answer Partitioned domains of responsibility Genetic algorithms may be suitable for long-term strategy but need more deterministic solutions for short term decision making

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