DOCSLIB.ORG

SDS 940 Timesharing Computer (Here in 1966, Later It Was the First Host to Connect to the Internet)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
SDS 940 Timesharing Computer (Here in 1966, Later It Was the First Host to Connect to the Internet) SDS 940 Timesharing Computer (Here in 1966, later it was the first host to connect to the Internet) Rick Crandall at the console of SDS 940 Computer Serial #2, September, 1966 at Comshare, Inc. The control panel is the central control hub of the historic Scientific Data Systems 940 computer made in July of 1966. The SDS 940 was the first computer designed specifically for on-line computing. It was also the first host computer ever to be connected to the “Internet” in October 1969 at the Stanford Research Institute. The 940’s basic operating system (i.e. the equivalent of Unix or Windows NT today) was created in 1966 as a collaboration of the U.C. Berkeley researchers, Rick Crandall of Comshare (Ann Arbor), Scientific Data Systems (Santa Monica) and Tymshare (Cupertino). Comshare continued the development into Commander I, its first commercial timesharing offering. As quoted from “Where Wizards Stay up Late, The Origins of the Internet”1 “A month after the first IMP2 was installed at UCLA, IMP Number Two arrived at SRI right on schedule on October 1, 1969… The SRI guys loved their host computer, an SDS 940… a revolutionary time-sharing system first put together by a team at Berkeley… With both IMP’s now in place, the moment to test the actual two-node ARPA3 network had finally arrived.” The test worked and the Internet was born. The 940 at SRI was serial #3 made by SDS. The one at Comshare was Serial #2. The ARPA network aimed at governmental and academic uses while Comshare and Tymshare opted for commercialized uses of the technology. 1. Katie Hafner and Matthew Lyon, Simon & Schuster, 1996: pp 149-152 2. Interface Message Processor, the computerized network switch for the internet, originally created by Bolt, Berenak & Newman 3. Advanced Research Projects Agency, the government agency who funded the early work on the Net..
Load more

Recommended publications
  • SDS 940 THEORY of OPERATION Technical Manual SDS 98 01 26A
    SDS 940 THEORY OF OPERATION Technical Manual SDS 98 01 26A March 1967 SCIENTIFIC DATA SYSTEMS/1649 Seventeenth Street/Santa Monica, California/UP 1-0960 ® 1967 Scientific Data Systems, Inc. Printed in U. S. A. TABLE OF CONTENTS Section Page I GENERAL DESCRIPTION ...•.••.•••••.••.••.•..•.••••• 1-1 1.1 General ................................... 1-1 1.2 Documentation .•...•..•.••..•••••••.•.••.••••• 1-1 1 .3 Physical Description ..•...•.••••.••..••••..••••. 1-2 1.4 Featu re s • . • . • • • • . • • • • • . • • . • . • . • • . • • • 1-2 1 .5 Input/Output Capabi I ity •.•....•.•.......•.....•.. 1-2 1 .5. 1 Parallel Input/Output System .•...•.....••..•. 1-6 1.5.1.1 Word Parallel System ...........•.. 1-6 1.5.1.2 Single-Bit Control and Sense System .... 1-8 1 .5.2 Time-Multiplexed Communication Channels .....•. 1-8 1 .5.3 Direct Memory Access System ............... 1-9 1.5.3.1 Direct Access Communication Channels •. 1-9 1.5.3.2 Data Multiplexing System ...•.....•. 1-10 1 .5.4 Priority Interrupt System . • . 1-10 1.5.4.1 Externa I Interrupt •..........•.... 1-11 1.5.4.2 Input/Output Channe I ..•..•.•••••. 1-12 1.5.4.3 Real-Time Clock •••.••.••••••••• 1-12 1 .6 Input/Output Devices •..•..••.••.••.••.•••••..•. 1-12 1 .6. 1 Buffered Input/Output Devices ..••.••.•.•••.•• 1-12 1.6.2 Unbuffered Input/Output Devices ••••..••••..•• 1-14 II OPERATION AND PROGRAMMING •..•••••.••.•..•....••. 2-1 2. 1 General .•..•.......•......•..............•. 2-1 2.2 Chang i ng Operat ion Modes •.•.••.••.•••.•..•..•.•• 2-2 2.3 Modes of Operation •..••.••.••.••..••••..••••••• 2-2 2.3. 1 Normal Mode .••••••••••••••••••••.••••• 2-2 2.3.1.1 Interrupt Rout i ne Return Instru ction .•.•. 2-3 2.3.1.2 Overflow Instructions ...••..•••••• 2-3 2.3.1.3 Mode Change Instruction ....••.•..• 2-3 2.3.1.4 Data Mu Itiplex Channe I Interlace Word •.
    [Show full text]
  • An Interview With
    An Interview with WARREN PRINCE OH 413 Conducted by Jeffrey R. Yost on 4 April 2012 Computer Services Project Sunnyvale, California Charles Babbage Institute Center for the History of Information Technology University of Minnesota, Minneapolis Copyright, Charles Babbage Institute Warren Prince Interview 4 April 2012 Oral History 413 Abstract Warren Prince was an executive at Tymshare and served as the leader of TYMNET. He served on the management team at McDonnell Douglas after it acquired TYMNET. The interview concentrates on TYMNET’s history and explaining and providing context to some of the documents he provided for the interview. 2 Prince: So will you produce the chapter in your book out of audio? I’ve got a bunch of papers that might be of interest or might not. Yost: Terrific, I would. Prince: Because it kind of shows; first, on the TYMNET side it shows the growth of it and really, the initial problems of it, which graphically shows it instead of saying it. And then the McDonnell Douglas part. Anyway, we can get into that when the time comes. Yost: Sounds good. My name is Jeffrey Yost, from the Charles Babbage Institute at the University of Minnesota, and I’m here today on April 4th, 2012, with Warren Prince of Tymshare and TYMNET. I’d like to begin just with some brief biographical stuff. Could you tell me where you were born, where you grew up? Prince: Born in Walnut Creek, California but grew up mostly in Arizona; Glendale, Arizona. And went through; started at the University of Arizona, and then joined the Army.
    [Show full text]
  • The Great Telecom Meltdown for a Listing of Recent Titles in the Artech House Telecommunications Library, Turn to the Back of This Book
    The Great Telecom Meltdown For a listing of recent titles in the Artech House Telecommunications Library, turn to the back of this book. The Great Telecom Meltdown Fred R. Goldstein a r techhouse. com Library of Congress Cataloging-in-Publication Data A catalog record for this book is available from the U.S. Library of Congress. British Library Cataloguing in Publication Data Goldstein, Fred R. The great telecom meltdown.—(Artech House telecommunications Library) 1. Telecommunication—History 2. Telecommunciation—Technological innovations— History 3. Telecommunication—Finance—History I. Title 384’.09 ISBN 1-58053-939-4 Cover design by Leslie Genser © 2005 ARTECH HOUSE, INC. 685 Canton Street Norwood, MA 02062 All rights reserved. Printed and bound in the United States of America. No part of this book may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording, or by any information storage and retrieval system, without permission in writing from the publisher. All terms mentioned in this book that are known to be trademarks or service marks have been appropriately capitalized. Artech House cannot attest to the accuracy of this information. Use of a term in this book should not be regarded as affecting the validity of any trademark or service mark. International Standard Book Number: 1-58053-939-4 10987654321 Contents ix Hybrid Fiber-Coax (HFC) Gave Cable Providers an Advantage on “Triple Play” 122 RBOCs Took the Threat Seriously 123 Hybrid Fiber-Coax Is Developed 123 Cable Modems
    [Show full text]
  • The People Who Invented the Internet Source: Wikipedia's History of the Internet
    The People Who Invented the Internet Source: Wikipedia's History of the Internet PDF generated using the open source mwlib toolkit. See http://code.pediapress.com/ for more information. PDF generated at: Sat, 22 Sep 2012 02:49:54 UTC Contents Articles History of the Internet 1 Barry Appelman 26 Paul Baran 28 Vint Cerf 33 Danny Cohen (engineer) 41 David D. Clark 44 Steve Crocker 45 Donald Davies 47 Douglas Engelbart 49 Charles M. Herzfeld 56 Internet Engineering Task Force 58 Bob Kahn 61 Peter T. Kirstein 65 Leonard Kleinrock 66 John Klensin 70 J. C. R. Licklider 71 Jon Postel 77 Louis Pouzin 80 Lawrence Roberts (scientist) 81 John Romkey 84 Ivan Sutherland 85 Robert Taylor (computer scientist) 89 Ray Tomlinson 92 Oleg Vishnepolsky 94 Phil Zimmermann 96 References Article Sources and Contributors 99 Image Sources, Licenses and Contributors 102 Article Licenses License 103 History of the Internet 1 History of the Internet The history of the Internet began with the development of electronic computers in the 1950s. This began with point-to-point communication between mainframe computers and terminals, expanded to point-to-point connections between computers and then early research into packet switching. Packet switched networks such as ARPANET, Mark I at NPL in the UK, CYCLADES, Merit Network, Tymnet, and Telenet, were developed in the late 1960s and early 1970s using a variety of protocols. The ARPANET in particular led to the development of protocols for internetworking, where multiple separate networks could be joined together into a network of networks. In 1982 the Internet Protocol Suite (TCP/IP) was standardized and the concept of a world-wide network of fully interconnected TCP/IP networks called the Internet was introduced.
    [Show full text]
  • SDS 900 Series, 1962
    The SDS 920 is a low cost, general purpose computer designed for sci- entific engineering computation and for systems integration. It has all the speed and operating features found only in much more expensive equipment, including instructions that facilitate floating-point and multi- precision operations. An evaluation of the 920's unequalled perform- ance-per-dollar capabilities can be made by comparing the following characteristics with any presently available digital computer: EXECUTION TIMES: All times include both memory access & indexing Add ........................................ 16 microseconds Mutiply ..................................... 32 microseconds Floating-Point Operations: (24-bit Mantissa plus 9-bit Exponent) Add ....................................292 mic~oseconds Multiply ............................... .248 microseconds (39-bit Mantissa plus 9-bit Exponent) Add ....................................368 microseconds Multiply ............................... .600 micmsecands PROGRAMMING: -- OENERAL PURPOSE COMPUTERS Control Pawl SI3S 4r09 &rim iDS 920 is a low cost, general purpose computer designed for sci- .......: engineering computation and for systems integration. It has all I the speed and operating features found only in much more expensive equipment, including instructions that facilitate floating-point and multi- precision operations. An evaluation of the 920's unequalled perform- per-dollar capabilities can be made by comparing the following 8 cteristics with any presently available digital computer: ' TYPE: Single address with indc g and indirect addressing Binary I Core Memory Solid State ructions for facilitating floating-point ,, iulti-precision opera1 , Parity checking on Input/Output and I sry Operations Prc ~---.dOperator magnetic core 4096 words expandable to 16,- ly addressable 24-bit word and parity Non- r include bot,' mory access & indexing ................ 16 microseconds ...................... 32 microseconds ...................292 micro .................. .248 microseconds bit Exponent ...............................
    [Show full text]
  • Tymnet Is Born
    The Bang! • August 1949 • Soviet RDS-1 • Valley Committee – Chair: George Valley • Technology R&D – Advanced RADAR – Advanced Computers – Advanced Networking • Boxcars of Cash The MIT Whirlwind Whirlwind was fitted with Core memory in 1953 as a part of the SAGE development project to develop something better than electrostatic memory. 22000 Sq Ft, 250 tons SAGE (Semi-Automatic Ground Environment) Enormous Comm. Network • Modems • Telephones • Fax Machines • Teleprinters • Radar Ckts Four Story Blockhouses • 3.5 acres of floor space • Hardened for 34 kPa overpressure • Two Computers in Duplex, each fills one floor, plus supporting equipment • Generators in smaller building • Enough Air Conditioning to cool 500 Arizona homes in summer, the electricity used would power 250 homes. Then Came Sputnik • US Defense Community reacted and threw even more money at Rand Corp and MIT and other think tanks, seeking a hardened network for military communications • ARPA began working on ARPANET Civilian Spin-offs - SABRE • Research proposal in 1953 • First system online in 1960 Civilian Spin-offs • ERMA – Electronic Recording Machine, Accounting • Bank of America and SRI • First ERMA system came online in 1959 Exploratory Demonstrations May 1965, Dave and Tom departed GE to work full-time on their dream Tymshare Associates Their business market is the science and engineering community around the South Bay Area Tymshare Incorporated • With funding in hand, the computer is ordered – Funded by $250,000 loan from BofA and SBA – Planned to use GE (Dartmouth
    [Show full text]
  • The Great Telecom Meltdown
    4 The Internet Boom and the Limits to Growth Nothing says “meltdown” quite like “Internet.” For although the boom and crash cycle had many things feeding it, the Internet was at its heart. The Internet created demand for telecommunications; along the way, it helped create an expectation of demand that did not materialize. The Internet’s commercializa- tion and rapid growth led to a supply of “dotcom” vendors; that led to an expec- tation of customers that did not materialize. But the Internet itself was not at fault. The Internet, after all, was not one thing at all; as its name implies, it was a concatenation [1] of networks, under separate ownership, connected by an understanding that each was more valuable because it was able to connect to the others. That value was not reduced by the mere fact that many people overesti- mated it. The ARPAnet Was a Seminal Research Network The origins of the Internet are usually traced to the ARPAnet, an experimental network created by the Advanced Research Projects Agency, a unit of the U.S. Department of Defense, in conjunction with academic and commercial contrac- tors. The ARPAnet began as a small research project in the 1960s. It was pio- neering packet-switching technology, the sending of blocks of data between computers. The telephone network was well established and improving rapidly, though by today’s standards it was rather primitive—digital transmission and switching were yet to come. But the telephone network was not well suited to the bursty nature of data. 57 58 The Great Telecom Meltdown A number of individuals and companies played a crucial role in the ARPAnet’s early days [2].
    [Show full text]
  • Notes on the History of Fork-And-Join Linus Nyman and Mikael Laakso Hanken School of Economics
    Notes on the history of fork-and-join Linus Nyman and Mikael Laakso Hanken School of Economics As part of a PhD on code forking in open source software, Linus Nyman looked into the origins of how the practice came to be called forking.1 This search led back to the early history of the fork system call. Having not previously seen such a history published, this anecdote looks back at the birth of the fork system call to share what was learned, as remembered by its pioneers. The fork call allows a process (or running program) to create new processes. The original is deemed the parent process and the newly created one its child. On multiprocessor systems, these processes can run concurrently in parallel.2 Since its birth 50 years ago, the fork has remained a central element of modern computing, both with regards to software development principles and, by extension, to hardware design, which increasingly accommodates parallelism in process execution. The fork system call is imagined The year was 1962. Melvin Conway, later to become known for “Conway’s Law,”3 was troubled by what seemed an unnecessary inefficiency in computing. As Conway recalls:4 I was in the US Air Force at the time – involved with computer procurement – and I noticed that no vendor was distinguishing between “processor” and “process.” That is, when a proposal involved a multiprocessor design, each processor was committed to a single process. By late 1962, Conway had begun contemplating the idea of using a record to carry the status of a process.
    [Show full text]
  • A History of the Personal Computer Index/11
    A History of the Personal Computer 6100 CPU. See Intersil Index 6501 and 6502 microprocessor. See MOS Legend: Chap.#/Page# of Chap. 6502 BASIC. See Microsoft/Prog. Languages -- Numerals -- 7000 copier. See Xerox/Misc. 3 E-Z Pieces software, 13/20 8000 microprocessors. See 3-Plus-1 software. See Intel/Microprocessors Commodore 8010 “Star” Information 3Com Corporation, 12/15, System. See Xerox/Comp. 12/27, 16/17, 17/18, 17/20 8080 and 8086 BASIC. See 3M company, 17/5, 17/22 Microsoft/Prog. Languages 3P+S board. See Processor 8514/A standard, 20/6 Technology 9700 laser printing system. 4K BASIC. See Microsoft/Prog. See Xerox/Misc. Languages 16032 and 32032 micro/p. See 4th Dimension. See ACI National Semiconductor 8/16 magazine, 18/5 65802 and 65816 micro/p. See 8/16-Central, 18/5 Western Design Center 8K BASIC. See Microsoft/Prog. 68000 series of micro/p. See Languages Motorola 20SC hard drive. See Apple 80000 series of micro/p. See Computer/Accessories Intel/Microprocessors 64 computer. See Commodore 88000 micro/p. See Motorola 80 Microcomputing magazine, 18/4 --A-- 80-103A modem. See Hayes A Programming lang. See APL 86-DOS. See Seattle Computer A+ magazine, 18/5 128EX/2 computer. See Video A.P.P.L.E. (Apple Pugetsound Technology Program Library Exchange) 386i personal computer. See user group, 18/4, 19/17 Sun Microsystems Call-A.P.P.L.E. magazine, 432 microprocessor. See 18/4 Intel/Microprocessors A2-Central newsletter, 18/5 603/4 Electronic Multiplier. Abacus magazine, 18/8 See IBM/Computer (mainframe) ABC (Atanasoff-Berry 660 computer.
    [Show full text]
  • SDS 925 Computer, 1964
    SOS 925 com uler r GENERAL CHARACTERISTICS The SDS 925 is a high-speed general purpose digital computer Series computer can be run on the 925 without modification. designed for scientific and engineering computation and for The entire line of field proven 900 Series peripherals-including real-time systems integration. The basic price of the 925 is SDS MAGPAK - can al so be used without modification. And, $81,000, including console, Model 35 Teletype Printer, Time like the SDS 900 Series computers, the 925 uses silicon Multiplexed Communication Channel, and 4095 words of semiconductors exclusively. Advanced SDS logical design memory. techniques result in the use of from two to five times fewer components than conventionally designed equipment. This The SDS 925 is fully compatible with SDS 900 Series com­ gives the 925 a significant reliability advantage over compar­ puters. Because of this compatabil ity, a complete set of field­ able computers. proven software is available, and programs written for any 900 THE SDS 925 HAS THE FOLLOWING CHARACTERISTICS: • 24-bit word plus a parity bit • 48-bit word for floating point arithmetic • Hardware Index Register; indexing requires no additional time • Basic memory of 4096 words, expandable to 16,384 words, all directly addressable, with: 0.7 p'sec access time 1.75 p'sec cycle time • Extensive shift and register change instructions for data manipulation • Execution times, including all access and indexing: FIXED POINT 3.5 p'sec Add 54.25 p.sec Multiply FLOATING POINT (24-bit fraction, 9-bit exponent)
    [Show full text]
  • Oral History Interview with Paul A. Strassmann
    An Interview with PAUL A. STRASSMANN OH 172 Conducted by Arthur L. Norberg on 26 May 1989 New Canaan, CT Charles Babbage Institute Center for the History of Information Processing University of Minnesota, Minneapolis Copyright, Charles Babbage Institute 1 Paul A. Strassmann Interview 26 May 1989 Abstract Strausmann begins the interview with a dicussion of the mainframe products of Xerox Data Systems (XDS), formerly Scientific Data Systems (SDS). From his perspective as Chief Computer Executive at Xerox, he describes the interaction betweeen XDS and Xerox's established copier business. Straussmann describes the growth of Xerox Palo Alto Research Center (Xerox PARC) and the development of the Alto and Star computers. Staussman recalls Xerox's decision to move away from computers and into integrated information technology. He concludes the interview with his comments on the changing economics of information technology for end users. 2 PAUL A. STRASSMANN INTERVIEW DATE: May 26, 1989 INTERVIEWER: Arthur L. Norberg LOCATION: New Canaan, Connecticut NORBERG: I am in the home of Mr. Paul A. Strassmann, New Canaan, Connecticut for the second interview on the Xerox Data years. Can we pick up where we left off the last time, Paul, and can you tell me a few things about your early tasks at Xerox when you were brought in by Mr. Flaven? STRASSMANN: The first task that I received upon joining Xerox on May 1, 1969, was to fly up to Boston to the Spring Joint Computer Conference, and have a good look at a Sigma 7 computer which was being exhibited for the first time.
    [Show full text]
  • The Computer History Simulation Project
    The Computer History Simulation Project The Computer History Simulation Project The Computer History Simulation Project is a loose Internet-based collective of people interested in restoring historically significant computer hardware and software systems by simulation. The goal of the project is to create highly portable system simulators and to publish them as freeware on the Internet, with freely available copies of significant or representative software. Simulators SIMH is a highly portable, multi-system simulator. ● Download the latest sources for SIMH (V3.5-1 updated 15-Oct-2005 - see change log). ● Download a zip file containing Windows executables for all the SIMH simulators. The VAX and PDP-11 are compiled without Ethernet support. Versions with Ethernet support are available here. If you download the executables, you should download the source archive as well, as it contains the documentation and other supporting files. ● If your host system is Alpha/VMS, and you want Ethernet support, you need to download the VMS Pcap library and execlet here. SIMH implements simulators for: ● Data General Nova, Eclipse ● Digital Equipment Corporation PDP-1, PDP-4, PDP-7, PDP-8, PDP-9, PDP-10, PDP-11, PDP- 15, VAX ● GRI Corporation GRI-909 ● IBM 1401, 1620, 1130, System 3 ● Interdata (Perkin-Elmer) 16b and 32b systems ● Hewlett-Packard 2116, 2100, 21MX ● Honeywell H316/H516 ● MITS Altair 8800, with both 8080 and Z80 ● Royal-Mcbee LGP-30, LGP-21 ● Scientific Data Systems SDS 940 Also available is a collection of tools for manipulating simulator file formats and for cross- assembling code for the PDP-1, PDP-7, PDP-8, and PDP-11.
    [Show full text]