2. MOBILE COMMUNICATION AND INTERNET TECHNOLOGIES Networking Technologies and Internet of the Future http://web.uettaxila.edu.pk/CMS/AUT2014/teMCITms/ Courtesy of: Dr. H. E. (Buster) Dunsmore Purdue University and Google Inc.

3. 2 MODULE AIMS  The main aims of this module are to:  Explore different networking technologies  Discuss future of Internet  Inter-Planetary Internet

4. NETWORKING TECHNOLOGY Power-Line Networking Way to connect computers in home or office using electrical wiring

5. More convenient than phone lines Connect computer to network through the outlet that provides power Data travels through electrical wiring Requires no new wiring and adds no cost to electric bill Power-line networking is inexpensive method for connecting computers in different places in home or office Power-Line Networking

6. 5 NETWORKS – HOME AREA NETWORKS (HAN) Network within a home  Connects digital devices HomePLC – electrical lines; cables connect card/USB/parallel port to wall outlet Phoneline – telephone lines; cables connect NIC/PC card to telephone jack Network card that plugs into PCI slot and wall outlet for home power-line network Howstuffworks.com HomeRF, 802.11b – radio waves; NIC connects to transceiver with antenna or to wireless access point Ethernet – twisted pair cables; Ethernet NIC cards and cables to connect devices

7. WIRELESS NETWORKING Creates network by sending infrared or radio signals between computers Better than Power-line networking; some computers are not “plugged in” to electrical outlet Laptop with wireless network card is completely portable throughout home or office IrDA (Infrared Direct Access) is standard for devices to communicate using infrared light pulses

8. Infrared devices must be in direct line of sight with each other (like TV remote… which uses same infrared technology) Infrared is almost always “one to one” technology Radio signals better because no line of sight requirement and ability to broadcast to multiple recipients WIRELESS NETWORKING

9. 8 NETWORK COMMUNICATIONS TECHNOLOGIES – 802.11, BLUETOOTH, IRDA IEEE 802.11 (802.11b, g – “WiFi”)  Family of standards used with wireless LANs  Used for public Internet access points Bluetooth  Devices contain special chip  Short-range radio waves transmit between Bluetooth devices  Short distance IrDA  IrDA devices contain IrDA ports  Infrared light waves  Line-of-sight transmission

10. BLUETOOTH Bluetooth is new standard being developed by a group of electronics manufacturers Will allow any sort of electronic equipment to communicate with each other Can be used among computers, keyboard, mouse, printer, headphone, cell phone Bluetooth-like radio communications should take place of wires or infrared signals for connecting devices

11. BLUETOOTH Very small radio module to be built into each device Wireless: No need for cables or cords to any device

12. Inexpensive: Should add only about $5-10 to price of product Simple: Devices find one another and strike up conversation without any work on your part Why is it called Bluetooth?  Harald Bluetooth was king of Denmark around the turn of the last millenium  He united Denmark and part of Norway into a single kingdom BLUETOOTH

13. Satellite Internet access already commonplace Satellites orbit at several hundreds of miles above Earth Imagine airplane-like device at approximately 60,000 feet Aircraft will be undisturbed by inclement weather and will be flying well above commercial air traffic AIRBORNE INTERNET

15. All satellite benefits without some of the problems Consumers would get connections comparable to Digital Subscriber Line (DSL) High-speed wireless Internet connection by placing aircraft in fixed pattern over city Could be lightweight planes (possibly unmanned) or blimps AIRBORNE INTERNET

16. Airborne Internet will function much like satellite-based Internet access, but without time delay Cost advantage over satellites – aircraft can be deployed easily – do not have to be launched into space Airborne Internet could even complement satellite and ground-based networks, not replace them AIRBORNE INTERNET

17. Impact: Possibility of constant connection to network anywhere, any time Benefit: Ease of connecting all computers and related devices Challenges: How to make most efficient use of the computing power, software, and tools always available How to build the most useful software and tools IMPACT AND OPPORTUNITY?

18. INTERNET TECHNOLOGY Access over the Internet to applications and services that would otherwise have to be located on one’s own personal computer Email, text editor, financial modeling software, Computer Aided Design (CAD) software, simulation software,….. Application Service Provider (ASP)

19. Centralized data storage, which will increase efficiency and ease of access to information, as well as synchronization of information among users and machines Wherever you are, that is your computer! STORAGE SERVICE PROVIDER (SSP)

20. About 120 universities and 25 corporate sponsors are working on better Internet infrastructure “Internet 2” THE NEXT GENERATION INTERNET

21. Larger bandwidth Faster speeds Better reliability Better security Better compression techniques (smaller files to be transmitted) Caching – leaving copies around closer to the point of need All developments will eventually become part of standard internet

22. INTERNET PROTOCOL VERSION 6 (IPV6) Today’s Internet uses Internet Protocol Version 4 (IPv4) – approximately 20 years old Internet Protocol Version 6 (IPv6) (also called IPng) will eventually replace IPv4

23. IPv6 fixes a number of problems in IPv4, such as limited number of available IPv4 addresses IPv6 goes from 32 to 128 bits per address If whole Earth was a beach, more than enough IP addresses for every grain of sand... hope that will be enough IPv6 also routes messages better, auto-configures for missing computers, and includes security components for encryption and authentication INTERNET PROTOCOL VERSION 6 (IPV6)

24. DECISION SUPPORT SYSTEMS, EXPERT SYSTEMS If Internet becomes repository of all knowledge, how best to use it? If Internet becomes repository of all knowledge, how best to use it? Decision Support Systems (DSS) access data, sophisticated analytical models, user-friendly interfaces

25. DECISION SUPPORT SYSTEMS, EXPERT SYSTEMS Can make repetitive, routine decisions with known algorithms Can provide alternatives and possible outcomes for more elaborate decisions Expert Systems (ES) capture decision-making rules used by experts Interaction with human user and available data evolved toward decision Neural networks can imitate DSS and ES and learn to make decisions

26. IMPACT AND OPPORTUNITY? Impact: Internet will provide fast access to enormous amount of information and tools for using that information Benefit: Immediate access for all kinds of information in a variety of formats (text, sound, image, video)  Ability to make decisions based on “all” available information… not just subset  Decision tools that represent best wisdom of all experts Challenge: How to sift through enormous quantity of information and tools available to decide what to use in any given situation

27. Researchers have recently made breakthroughs in developing displays out of polyethylene terephthalate (PET) Thin, flexible, rugged plastic that you can bend, roll up, fold, or form into practically any shape CONSUMER COMPUTER TECHNOLOGY Plastic Displays

28. PLASTIC DISPLAYS Mass production of plastic displays is approximately five years away Applications could include notebook and desktop displays, hand-held appliances Also, wearable displays sewn into clothing, and paper thin electronic books and newspapers

29. ELECTRONIC DIGITAL PAPER Developed at Xerox Palo Alto Research Center (PARC), electronic paper is new kind of display Somewhere between paper and conventional computer screen

30. ELECTRONIC DIGITAL PAPER Like paper, it is thin, lightweight, and flexible Like computer display, it is dynamic and rewritable Wide range of potential applications, including:  Electronic paper newspapers offering breaking news, incoming sports scores, and up to the minute stock quotes, even as paper is being read  Electronic paper magazines that continually update with breaking information and make use of animated images or movie pictures  Electronic paper textbooks, which could be updated as technology changes

31. ELECTRONIC DIGITAL PAPER Electronic paper utilizes new display technology called gyricon  A gyricon sheet is thin layer of transparent plastic in which millions of small beads, like toner particles, are randomly dispersed  Beads are bichromal, with hemispheres of contrasting color  Under influence of voltage applied to surface of sheet, beads rotate to present one colored side or the other to the viewer  Image will persist until new voltage patterns are applied to create new images

32. POWER PAPER Computers and other electronic devices becoming thinner and thinner Soon laptop computer could be as thin as a sheet of paper Power supplies must slim down as well Power Paper, an Israel-based company, has developed paper-thin battery technology

33. POWER PAPER Power electronic devices, games, greeting cards, smart cards, luggage tags, medical devices Imagine smart tickets to sporting events to avoid counterfeiting and give directions to seat Could be very useful in computerized clothing and wearable computers Power Paper cell will be one-half millimeter thick, and will generate 1.5 volts

34. PRINTABLE COMPUTERS Researchers developing ink- based, plastic processor

35. PRINTABLE COMPUTERS Printable computer components not designed to replace silicon (about 100 times slower) Plastic offers some benefits over silicon  Silicon is rigid, while plastic chips are flexible Will lead to simple computers to give intelligence to everyday objects Could be integrated into clothes, food labels, simple appliances, toys

36. WEARABLE COMPUTERS Obvious applications like hearing aids with sound enhancement software “Glasses” with multi- informational display about what is being seen, where you are Wrist computers, PDAs, cell phones Next step is computerized clothing Including computers in standard clothing items like shoes, pants, shirts, jackets, belts…

37. WEARABLE COMPUTERS Uses include…. Health related – monitor blood pressure, pulse rate, blood sugar, useful for life threatening conditions that need continual monitoring Navigation – directions, maps, airline information, restaurant and hotel information Safety and security – connections to police, fire, medical, auto towing and repair Entertainment – music, news, video, sporting events

38. WEARABLE COMPUTERS Some of these devices already making their way into consumer market Working to integrate computers and related devices directly into clothing, so that they are virtually invisible Interaction via sensors, all fabric keypads, speakers, voice recognition receivers, thin light- emitting diode (LED) monitors, flat screen (plastic) displays, holographic projectors Another step in making computers and devices portable without having to carry and manipulate plethora of gadgets

39. COMPUTERS IN EVERY IMAGINABLE ITEM Appliances – Home security, heating/air conditioning, refrigerator, oven, dishwasher, lighting system, entertainment systems, washer, dryer, garage door opener, “watering” systems Vehicles – cars, bicycles, lawn mowers, snow blowers, chain saws

40. VOICE RECOGNITION Many of above will operate via voice commands Next 3-5 years will bring major advances in speech recognition Voice is converted into phonemes (basic elements of speech)  English language has approximately 50 phonemes

41. VOICE RECOGNITION Phonemes compared to dictionary of words stored via phonemes  Words then translated into computer commands like “Display nearest gas station?”  Limited vocabulary systems and systems trained to particular person’s speech will be very fast and precise Voice recognition requires tremendous storage and processing power – no problem

42. IMPACT AND OPPORTUNITY? Impact: Every conceivable device can have computer embedded in it Benefit: Any mundane activity (like monitoring supply of food in refrigerator) or complex activity (like amplifying only specific sound frequencies in hearing aid) can be done by computer Challenge: How to design most useful cadre of consumer computers to aid without overwhelming us humans

43. Magnetic Random Access Memory (MRAM) has potential to store more data, access data faster, use less power than current memory technologies Could eliminate computer “boot up” sequence Today’s memory Dynamic RAM (DRAM) needs to be supplied with constant current to store bits of data COMPUTER PROCESSORS AND STORAGE TECHNOLOGY Magnetic Ram

44. MAGNETIC RAM If current turned off, everything has to be stored again In MRAM, small amount of electricity needed only to switch polarity (1 or 0) of each memory cell on the chip…not to maintain that value

45. HOLOGRAPHIC STORAGE TECHNOLOGIES CDs, DVDs, and magnetic storage all store bits of information on the surface of a recording medium To increase storage capabilities, new optical storage method, called holographic memory, will go beneath the surface and use volume of recording medium for storage Could offer more storage in same space

46. EXTREME-ULTRAVIOLET LITHOGRAPHY (EUVL) CHIPS Current silicon technology used to make microprocessors has begun to reach its limit since 2005 Other technologies necessary to cram more transistors onto silicon to create more powerful chips Extreme-ultraviolet lithography (EUVL) – way to extend life of silicon at least until the end of the decade

47. EXTREME-ULTRAVIOLET LITHOGRAPHY (EUVL) CHIPS Using extreme-ultraviolet light to carve transistors in silicon wafers will lead to microprocessors as much as 100 times faster than today’s most powerful chips Memory chips with similar increases in storage capacity

48. DNA COMPUTERS Microprocessors made of silicon will eventually reach their limits of speed and miniaturization Chip makers need new material to produce faster computing speeds Millions of natural supercomputers exist in living organisms DNA (deoxyribonucleic acid) molecules have potential to perform calculations many times faster than the world’s most powerful human-built supercomputers

49. DNA COMPUTERS DNA might one day be integrated on a computer chip to create a so-called biochip that will push computers even faster DNA molecules have already been harnessed to perform complex mathematical problems Large supply of DNA makes it a cheap resource DNA’s key advantage is that it will make computers smaller, while holding more data, than any computer that has come before

50. DNA COMPUTERS One pound of DNA has the capacity to store more information than all electronic computers ever built Teardrop-sized DNA computer will be more powerful than world’s current most powerful supercomputer Unlike conventional computers, DNA computers perform calculations in parallel

51. IMPACT AND OPPORTUNITY? Impact: Computers will be smaller, faster, lighter with enormous amounts of storage capacity Benefit: Any imaginable task can be programmed to be executed in “real time” (like monitoring aspects of nuclear reactor) Challenge: What is the most cost-effective use of these technologies? How can we keep the “smaller, faster, lighter” development going?

52. Research on computer use for vision-impaired leading to touch screens with digitally-controlled raised surfaces Digital Scent Synthesizer SOME “FAR OUT” POTENTIAL FUTURE DEVELOPMENTS The Forgotten Senses (Touch, Smell, Taste) The Forgotten Senses (Touch, Smell, Taste)

53. THE FORGOTTEN SENSES (TOUCH, SMELL, TASTE) Indexed thousands of smells based on chemical structure and place on scent spectrum Each scent is coded and digitized into small file Digital file is embedded in Web content or email (much like image file) User may request scent or may be unleashed automatically Create thousands of everyday scents with small cartridge containing 128 primary odors Similar research going on in digital taste synthesis

54. ROBOTICS Because of advances in processors, memory, decision support systems, expert systems, sensors…. Today’s crude robots will become “thinking” machines, capable of behavior that mimics reason, emotion, common sense, speech, vision, locomotion

55. 54 IBM 360/75 #3 UCSB PDP 10 SDS 940 #2 SRI #4 UTAH #1 UCLA SDS Sigma 7 The Original ARPANET Dec 1969

56. 55 Internet 1999

57. 56 INTERNET - GLOBAL STATISTICS 2008 (approx. 3.5 B mobiles and 1 Billion PCs) 542 Million Hosts (ISC Jan 2008) 1,464 Million Users (InternetWorldStats.com, June 30, 2008)

58. 57 REGIONAL INTERNET STATISTICS 6/30/08 RegionInternet Population % penetration Asia578.5 Mil.15.3 % Europe384.6 Mil.48.1 % North Am.248.2 Mil.73.6 % LATAM/C139.0 Mil.24.1 % Mid-East 41.9 Mil.21.3 % Oceania 20.2 Mil.59.5 % Africa 51.0 Mil. 5.3 % TOTAL1,463.6 Mil.21.9 %

59. 58 INTERNET-ENABLED DEVICES

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64. 63 InterPlaNetary Internet

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70. 69 INTERPLANETARY INTERNET:“INTERPLANET” (IPN) Planetary internets Interplanetary Gateways Interplanetary Long-Haul Architecture(RFC 4838)  Licklider Transport Protocol (LTP)  Bundle Protocol (RFC 5050)  Delayed Binding of Identifiers  Email-like behavior TDRSS and NASA in-space routing Delay and Disruption Tolerant Protocols  Tactical Mobile applications (DARPA)  Civilian Mobile applications (SameNet!)  Deep Impact Testing October/November 2008  Space Station Testing 2009

71. 70 End-to-end information flow across the solar system Layered architecture for evolvability and interoperability IP-like protocol suite tailored to operate over long round trip light times Integrated communications and navigation services

72. Q A &

73. ASSIGNMENT #4  Write note on terms highlighted in Red in this lecture  Describe the ARPA NET architecture highlighting the universities and research facilities that shared online the resources of their mainframe servers as shown on slide 54