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Physical Infrastructure. Week 1 INFM 603. Agenda. Computers The Internet The Web About the course. A Very Brief History of Computing. Hardware Mechanical: essentially a big adding machine Analog: designed for calculus, limited accuracy Digital: early machines filled a room
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Physical Infrastructure Week 1 INFM 603
Agenda • Computers • The Internet • The Web • About the course
A Very Brief History of Computing • Hardware • Mechanical: essentially a big adding machine • Analog: designed for calculus, limited accuracy • Digital: early machines filled a room • Microchips: designed for missile guidance • Software • Numeric: computing gun angles • Symbolic: code-breaking
Input Devices • Text • Keyboard, optical character recognition • Speech recognition, handwriting recognition • Direct manipulation • 2-D: mouse, trackball, touchpad, touchscreen • 3-D: wand, data glove • Remote sensing • Camera, speaker ID, head tracker, eye tracker
InputExample: QWERTY Keyboard From http://home.earthlink.net/~dcrehr/whyqwert.html
Dvorak Keyboard From http://www.mwbrooks.com/dvorak/
Binary Data Representation Example: American Standard Code for Information Interchange (ASCII) 01000001 = A 01000010 = B 01000011 = C 01000100 = D 01000101 = E 01000110 = F 01000111 = G 01001000 = H 01001001 = I 01001010 = J 01001011 = K 01001100 = L 01001101 = M 01001110 = N 01001111 = O 01010000 = P 01010001 = Q … 01100001 = a 01100010 = b 01100011 = c 01100100 = d 01100101 = e 01100110 = f 01100111 = g 01101000 = h 01101001 = i 01101010 = j 01101011 = k 01101100 = l 01101101 = m 01101110 = n 01101111 = o 01110000 = p 01110001 = q …
Output Devices • Visual • Screen, projector, head-mounted display, CAVE • Acoustic • Speakers, headphones • Physical • Tactile (vibrotactile, pneumatic, piezoelectric) • Force feedback (pen, joystick, exoskeleton) • Thermal • Vestibular (motion-based simulators) • Locomotive (treadmill, stationary bicycle) • Olfactory
Extracted From Shelly Cashman Vermatt’s Discovering Computers 2004
The Big Picture Memory Processor Network
Hardware Processing Cycle • Input comes from somewhere • Keyboard, mouse, microphone, camera, … • The system does something with it • Processor, memory, software, network, … • Output goes somewhere • Monitor, speaker, robot controls, …
Computer Hardware • Central Processing Unit (CPU) • Intel Xeon, Motorola Power PC, … • Communications “Bus” • FSB, PCI, ISA, USB, Firewire, … • Storage devices • Cache, RAM, hard drive, floppy disk, … • External communications • Modem, Ethernet, GPRS, 802.11, …
The Storage Hierarchy • Speed, cost, and size: • You can easily get any 2, but not all 3 • Fast memory is expensive • So large memory is slow! • But fast access to large memories is needed • Solution: • Keep what you need often in small (fast) places • Keep the rest in large (slow) places • Get things to the fast place before you need them
Best of Both Worlds Small, but fast… = + Is Large and seems fast Large, but slow… Think about your bookshelf and the library…
Locality • Spatial locality: • If the system fetched x, it is likely to fetch data located near x • Temporal locality: • If the system fetched x, it is likely to fetch x again
System Architecture Keyboard Mouse Sound Card Video Card Input Controller System Bus Front Side Bus Hard Drive CD/ DVD USB Port L2 RAM CPU L1 Cache Motherboard
Everything is Relative • The CPU is the fastest part of a computer • 3 GHz Core 2 Duo = 6,000 MIPS • 3 operations per processor every nanosecond • Cache memory is fast enough to keep up • 128 kB L1 cache on chip (dedicated, CPU speed) • 4 MB L2 cache on chip (shared, CPU speed) • RAM is larger, but slower • 1 GB or more, ~6 ns
“Solid-State” Memory • ROM • Does not require power to retain content • Used for “Basic Input/Output System” (BIOS) • Cache (Fast low-power “Static” RAM) • Level 1 (L1) cache: small, single-purpose • Level 2 (L2) cache: larger, shared • (“Dynamic”) RAM (Slower, power hungry) • Reached over the “Front-Side Bus” (FSB) • Flash memory (fast read, slow write EEPROM) • Reached over USB bus or SD socket • Used in memory sticks (“non-volatile” storage)
System Architecture Keyboard Mouse Sound Card Video Card Input Controller System Bus Front Side Bus Hard Drive CD/ DVD USB Port L2 RAM CPU L1 Cache Motherboard
“Rotating” Memory • Fixed magnetic disk (“hard drive”) • May be partitioned into multiple volumes • In Windows, referred to as C:, D:, E:, … • In Unix, referred to as /software, /homes, /mail, … • Removable magnetic disk • Floppy disk, zip drives, … • Removal optical disk • CDROM, DVD, CD-R, CD-RW, DVD+RW, …
How Disks Work Extracted From Shelly Cashman Vermatt’s Discovering Computers 2004
RAID-5 • Disks can fail in two ways: • Bad sectors (data sectors, directory sectors) • Mechanical failure • RAID-5 arrays “stripe” blocks across disks • “Parallel” data transfer is faster than “serial” • ~30% “parity” allows reconstruction if one disk fails
Moore’s Law • Processing speed doubles every 18 months • Faster CPU, longer words, larger cache, more cores • Cost/bit for RAM drops 50% every 12 months • Less need for “virtual memory” • Cost/bit for disk drops 50% every 12 months • But transfer rates don’t improve much
Agenda • Computers • The Internet • The Web • About the course
Network • Computers and devices connected via • Communication devices • Transmission media
Packet vs. Circuit Networks • Telephone system (“circuit-switched”) • Fixed connection between caller and called • High network load results in busy signals • Internet (“packet-switched”) • Each transmission is routed separately • High network load results in long delays
Packet Switching • Break long messages into short “packets” • Keeps one user from hogging a line • Route each packet separately • Number them for easy reconstruction • Request retransmission for lost packets • Unless the first packet is lost!
Networks of Networks • Local Area Networks (LAN) • Connections within a room, or perhaps a building • Wide Area Networks (WAN) • Provide connections between LANs • Internet • Collection of WANs across multiple organizations
Local Area Networks • Within a campus or an office complex • Short-distance lines are fast and cheap • Fast communications makes routing simple • Ethernet is a common LAN technology • All computers are connected to the same cable • Ordinary phone lines can carry 10 Mb/sec • 100 Mb/s connections require special cables • 1 Gb/s connections require special switches • Every host broadcasts everything to all others • Collisions limit throughput to about 50% utilization
Shared Network • All attach to the same cable • Ethernet and “cable modems” • Transmit anytime • Collision detection • Automatic retransmission • Inexpensive and flexible • Easy to add new machines • Robust to computer failure • Practical for short distances • Half the bandwidth is wasted
Switched (“Star”) Network • All attach directly to a hub • Switched Ethernet • Digital Subscriber Lines (DSL) • Higher cost • Line from hub to each machine • Hub must handle every packet • Hub requires backup power • Much higher bandwidth • No sharing, no collisions • Allows disks to be centralized
Wireless Networks • Radio-based Ethernet • Effective for a few rooms within buildings • “Access Point” gateways to wired networks • Available throughout most of the Maryland campus • Commercial providers offer “hot spots” in airports, etc. • “WiFi WLAN” is available in several speeds • IEEE 802.11b: 10Mb/s (good enough for most uses) • IEEE 802.11g: 54Mb/s (required for wireless video) • IEEE 802.11n: 248Mb/s (and longer range) • Computer-to-computer networks are also possible • “Bluetooth” is the most common (very short range)
Wide Area Networks • Campus, regional, national, or global scale • Expensive communications must be used well • Limiting to two hosts allows 100% utilization • Routing is complex with point-to-point circuits • Which path is shortest? Which is least busy? …
“Backbone” Microwave Satellite Fiber “Last mile” wired Telephone modem ADSL Cable modem Fiber “Last mile” wireless Wi-Fi (IEEE 802.11) GSM Types of Digital Channels