1 / 60

8-11-2007

8-11-2007. (Lecture 2). CS8421 Computing Systems Dr. Jose M. Garrido. Class Will Start Momentarily…. Vehicle systems Traffic control Process control Medical systems Military RT systems Manufacturing Robots systems Security control. Telecommunication systems Computer games

Patman
Télécharger la présentation

8-11-2007

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 8-11-2007 (Lecture 2) CS8421 Computing SystemsDr. Jose M. Garrido • Class • Will • Start • Momentarily…

  2. Vehicle systems Traffic control Process control Medical systems Military RT systems Manufacturing Robots systems Security control Telecommunication systems Computer games Multimedia systems Household appliance monitoring & control Building energy control Real-Time Applications and Examples

  3. Properties of Real-Time Systems • Timeliness - the system must perform operations in timely manner • Reactiveness - the system continuously responds to (random) events • Concurrency - multiple simultaneous activities are carried out • Distribution - tasks cooperate in multiple computing sites

  4. RTS Time Issues • The goal is to reduce two specific intervals: • service time - the interval taken to compute a response to a given input • latency - the interval between the time of occurrence of an input and the time at which it starts being serviced • The sum of these two intervals represents the response time. This must be shorter than the deadline for this type of input.

  5. Architecture • Architecture refers to the attributes visible to the programmer • Instruction set • Number of bits used for data representation • I/O mechanisms • Addressing techniques. • Is there a multiply instruction?

  6. Organization • Organization refers to how features are implemented • Control signals • Interfaces • Memory technology. • Is there a hardware multiply unit or is it done by repeated addition?

  7. Architecture & Organization • All Intel x86 family share the same basic architecture • The IBM System/370 family share the same basic architecture • This gives code compatibility • At least backwards • Organization differs between different versions

  8. Structure & Function • Structure is the way in which components relate to each other • Function is the operation of individual components as part of the structure

  9. Computer Architecture Overview Components of a computer system: • CPU • Main Memory • Secondary Storage • I/O Devices • Bus • Operating System

  10. General System Structure

  11. Computer Functions The computer functions are: • Data processing • Data storage (memory) • Data movement (I/O) • Control

  12. Computer Functional View

  13. Data Movement

  14. Data Storage

  15. Processing from/to Storage

  16. Processing from Storage to I/O

  17. Structure - Top Level Computer Peripherals Central Processing Unit Main Memory Computer Systems Interconnection Input Output Communication lines

  18. Structure - The CPU CPU Arithmetic and Logic Unit Computer Registers I/O System Bus CPU Internal CPU Interconnection Memory Control Unit

  19. Structure - The Control Unit Control Unit CPU Sequencing Logic ALU Control Unit Internal Bus Control Unit Registers and Decoders Registers Control Memory

  20. ENIAC - background • Electronic Numerical Integrator And Computer • Eckert and Mauchly • University of Pennsylvania • Trajectory tables for weapons • Started 1943 • Finished 1946 • Too late for war effort • Used until 1955

  21. ENIAC - Details • Decimal (not binary) • 20 accumulators of 10 digits • Programmed manually by switches • 18,000 vacuum tubes • 30 tons • 15,000 square feet • 140 kW power consumption • 5,000 additions per second

  22. von Neumann/Turing • Stored Program concept • Main memory store programs and data • ALU operating on binary data and binary code • Control unit interpreting instructions from memory and executing • Input and output equipment operated by control unit • Princeton Institute for Advanced Studies • IAS • Completed 1952

  23. Structure of von Neumann Machine

  24. IAS - details • 1000 x 40 bit words • Binary number • 2 x 20 bit instructions • Set of registers (storage in CPU) • Memory Buffer Register • Memory Address Register • Instruction Register • Instruction Buffer Register • Program Counter • Accumulator • Multiplier Quotient

  25. Structure of IAS – detail

  26. Functioning of the IAS Computer • Repetitively performing an instruction cycle • An instruction cycle has two subcycles • Fetch cycle – the “opcode” of instruction and its address are loaded into registers IR and MAR • Execute cycle -- interpretation of the “opcode” and execution of the instruction

  27. Instructions of the IAS Computer • The IAS computer had 21 instructions • These instructions are grouped as: • Data transfer • Unconditional branch • Conditional branch • Arithmetic • Address modify

  28. Commercial Computers • 1947 - Eckert-Mauchly Computer Corporation • UNIVAC I (Universal Automatic Computer) • US Bureau of Census 1950 calculations • Became part of Sperry-Rand Corporation • Late 1950s - UNIVAC II • Faster • More memory

  29. IBM • Punched-card processing equipment • 1953 - the 701 • IBM’s first stored program computer • Scientific calculations • 1955 - the 702 • Business applications • Lead to 700/7000 series • The IBM 7094 introduced the data channel, a smaller specialized I/O processor

  30. Transistors • Replaced vacuum tubes • Smaller • Cheaper • Less heat dissipation • Solid State device • Made from Silicon (Sand) • Invented 1947 at Bell Labs • William Shockley et al.

  31. Transistor Based Computers • Second generation machines • NCR & RCA produced small transistor machines • IBM 7000 • DEC - 1957 • Produced PDP-1

  32. Microelectronics • Literally - “small electronics” • A computer is made up of gates, memory cells and interconnections • These can be manufactured on a semiconductor • e.g. silicon wafer • Used in the third generation of computers

  33. Generations of Electronics • Vacuum tube - 1946-1957 • Transistor - 1958-1964 • Small scale integration - 1965 on • Up to 100 devices on a chip • Medium scale integration - to 1971 • 100-3,000 devices on a chip • Large scale integration - 1971-1977 • 3,000 - 100,000 devices on a chip • Very large scale integration - 1978 to date • 100,000 - 100,000,000 devices on a chip • Ultra large scale integration • Over 100,000,000 devices on a chip

  34. Moore’s Law • Increased density of components on chip • Gordon Moore - cofounder of Intel • Number of transistors on a chip will double every year • Since 1970’s development has slowed a little • Number of transistors doubles every 18 months • Cost of a chip has remained almost unchanged • Higher packing density means shorter electrical paths, giving higher performance • Smaller size gives increased flexibility • Reduced power and cooling requirements • Fewer interconnections increases reliability

  35. Growth in CPU Transistor Count

  36. IBM 360 series • 1964 • Replaced (& not compatible with) 7000 series • First planned “family” of computers • Similar or identical instruction sets • Similar or identical O/S • Increasing speed • Increasing number of I/O ports (i.e. more terminals) • Increased memory size • Increased cost • Multiplexed switch structure

  37. DEC PDP-8 • 1964 • First minicomputer • Did not need air conditioned room • Small enough to sit on a lab bench • $16,000 • $100k+ for IBM 360 • Embedded applications & OEM • BUS STRUCTURE

  38. DEC - PDP-8 Bus Structure I/O Module Main Memory I/O Module Console Controller CPU OMNIBUS

  39. Semiconductor Memory • 1970 • Fairchild • Size of a single core • i.e. 1 bit of magnetic core storage • Holds 256 bits • Non-destructive read • Much faster than core • Capacity approximately doubles each year

  40. Intel • 1971 - 4004 • First microprocessor • All CPU components on a single chip • 4 bit • Followed in 1972 by 8008 • 8 bit • Both designed for specific applications • 1974 - 8080 • Intel’s first general purpose microprocessor

  41. Improving Speed • Pipelining • On board cache • On board L1 & L2 cache • Branch prediction • Data flow analysis • Speculative execution

  42. Performance Mismatch • Processor speed increased • Memory capacity increased • Memory speed lags behind processor speed

  43. DRAM and Processor Characteristics

  44. Trends in DRAM use

  45. Pentium Evolution (1) • 8080 • first general purpose microprocessor • 8 bit data path • Used in first personal computer – Altair • 8086 • much more powerful • 16 bit • instruction cache, prefetch few instructions • 8088 (8 bit external bus) used in first IBM PC • 80286 • 16 Mbyte memory addressable • up from 1Mb • 80386 • 32 bit • Support for multitasking

  46. Pentium Evolution (2) • 80486 • sophisticated powerful cache and instruction pipelining • built in maths co-processor • Pentium • Superscalar • Multiple instructions executed in parallel • Pentium Pro • Increased superscalar organization • Aggressive register renaming • branch prediction • data flow analysis • speculative execution

  47. Pentium Evolution (3) • Pentium II • MMX technology • graphics, video & audio processing • Pentium III • Additional floating point instructions for 3D graphics • Pentium 4 • Note Arabic rather than Roman numerals • Further floating point and multimedia enhancements • Itanium • 64 bits

  48. PowerPC • IBM, Motorola, Apple • Used in Apple Macintosh • RISC architecture • 601 • 603 • 604 • 620 • 740/750 (G3) • G4 • G5

  49. What is a Program? • A sequence of steps (instructions?) • For each step, an arithmetic or logical operation is carried out • For each operation, a different set of control signals is needed

  50. Function of Control Unit • For each operation a unique operationcode is provided • e.g. ADD, MOVE • A hardware segment accepts the code and issues the control signals • This is the foundation for a computer!

More Related