DOCSLIB.ORG

The Hard-Disk Explosion, August 1980, BYTE Magazine

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Hard-Disk Explosion, August 1980, BYTE Magazine The Hard-Disk Explosion High-Powered Mass Storage for Your Personal Computer Tom Manuel 1208 Apollo Way, Suite 502 Sunnyvale CA 94086 High-performance, high-quality, new small sizes-200 mm (7.87 inch) drives, especially where multiple and large-capacity hard-disk drives or 210 mm (8.27 inch) diameter-and drives would normally be neces­ are now a low-cost reality for your one new drive uses 130 mm (5.12 sary to obtain enough storage. personal-computer system. Most inch) platters. Even so, their data For example, instead of adding hard disks use Winchester media, capacities are significantly larger than more floppy drives to increase head technology, and other modern floppy-disk drives of the same ap­ the storage capacity of a system, techniques to achieve high density proximate size. one set of dual floppy-disk drives and high performance in a small The latest disk drives can be divid­ might be replaced with an 8-inch space. One side effect is low power ed into two general categories: hard-disk drive that fits in the consumption. Some of the drives suit­ same space. This improves the able for personal computers use the • low-cost, relatively low­ storage capacity and system per­ older 14-inch standard diameter plat­ performance drives that will formance dramatically. These ters. Many new drives use one of two eventually replace floppy-disk low-end disk products will com­ pete on a cost-per-drive basis. • high-capacity, top-performance drives that must compete on a cost-per-byte basis. The 8-inch or smaller versions will likely (at least at first) be more costly per byte than the 14-inch models. However, their advantages of small size, light weight, low noise, and low power re­ quirements make them very at­ tractive for desktop and personal computers as well as small business systems. The Winchester disk-drive tech­ nology developed by IBM provided expensive, large-capacity, high-per­ formance, and low cost-per-byte disk subsystems (ie: the IBM 3350 and 3370 disk-drive systems) for large, ex­ pensive computer systems. This technology and development in other areas of disk-drive performance are now being applied to the develop­ ment of products suitable for smaller systems. The tremendous growth of Photo 1: The Memorex Model 101 hard-disk drive. (Photo courtesy of Memorex') microcomputers has created a de- 58 August 1960 © BYTE Publications Inc mand for small, compact disk drives. What Is Winchester T echnology7 • thinner magnetic coating: 44 The industry has responded and is be­ Three disk technologies have micro inches versus 185 micro­ ginning to produce them. A evolved, all pioneered by IBM. Other inches in the 2314 disk drive Winchester disk drive for your per­ manufacturers have refined the • lubricated disk surfaces sonal computer is now, or soon will designs. These technologies are usual­ • heads resting on disk surface be, a possibility. However, it may ly referred to by the model numbers when drive is stopped-they take still cost you five to ten times the of the original IBM product employ­ off and fly low when motion price of your processor to get a com­ ing the technology: "2314" starts (normal take-off and land­ plete small hard-disk subsystem with technology (in the 1960s), "3330" ing are done on an area reserved drive, controller, interface, power technology (late 1960s, early 1970s), for that purpose) supply, and packaging. and 'Winchester" technology (1973). • light loading force (10 g) and Disk storage, being a special type lighter heads. of add-on memory, can directly affect a computer system's performance, These characteristics permit many throughput, and reliability. Because performance improvements: very low of this crucial role, the principal flying heights (19 to 20 microinches), design objectives for disks are large improved reliability, and a dramatic capacity, fast access time, absolute reduction in head crashes are possible reliability, and low cost. because of the clean environment, Each of the three advances has new head and loading designs, and brought a significant increase in lubrication. Data densities are in­ storage density. One way to increase creased because of lower flying height density is to reduce the flying height and thinner platter coating. The of the heads over the disk surface. higher densities improve throughput Each reduction in height allows an in­ performance directly. More bits per crease in: tpi (tracks per inch) and bpi inch allow more data to pass under (bits per inch) (see figure 1). Ad­ the heads per unit time. More tracks vances in head design and positioning per inch mean that track-to-track ac­ mechanisms have also contributed to cess times are shorter. The lighter increases in tpi and bpi. heads and head mounts have less in­ Head flying heights have evolved ertia and can be positioned faster. as shown in table 1. Throughput performance can be im­ Photo 2: Close-up of a Winchester-type Just prior to 1973, disk-drive proved by increasing the rotational read/ write head. (Photo courtesy of Kennedy Company.) technology approached some limits. speed, up to a point-the aero­ The flying height had been reduced to dynamic characteristics of the flying 31 microinches. Without further head put some constraints on the reduction, significant improvement in rotational speed. The reliability of the data density was difficult. At lower Winchester drives surpassed that of flying heights, a single smoke parti­ any moving-head disk drive that was cle, whose diameter may be up to ten previously available. times the distance between the head Improvements and refinements and disk surface, can damage the disk have continued from many manufac­ and data. Therefore, cleaner condi­ turers. The costs of many of the most tions were required. Also, the disk expensive elements in a disk (the platters and magnetic surfaces were motor, head actuator, and control inadequate for large increases in track electronics) are relatively indepen­ and bit densities. dent of the capacity of the disk plat­ The 3340 Winchester disk drive, in­ ters. It is, therefore, cost-effective to troduced by IBM in 1973, was the increase the density of the platters first breakthrough. Storage and the number of platters. The in­ Technology Corporation announced centive has been to add capacity by a similar disk drive around the same any conceivable means, and trends time: the STC 8800 superdisk. have been toward more platters per spindle and greater bpi and tpi den­ Winchester Characteristics sities (data density has gone from Photo 3: The remarkable Shugart Winchester disk drives have the about 1000 bpi on early 2314s to over Technology Model ST506 hard-disk following characteristics: 8600 bpi on some of the recent disks, drive, offering 6 megabytes of mass and tpi density has gone from 200 tpi storage in a 3.5-pound package that fits in • sealed disk, head, and position­ on 2314s to over 600 tpi on new pro­ the ' same space as a 5-inch floppy-disk ducts). Cost effectiveness has also drive. (Shugart Technology is a new com­ ing assemblies pany located in Scotts Valley, California, • new trimaran head design-two been enhanced by reducing the access and is not affiliated with either Shugart outriggers supporting a narrower time and increasing the data flow; the Associates or Xerox. Photo courtesy of inner hull containing the economic payoff is increased Shugart Technology.) read/write head (see photo 2) throughput and efficiency of the total 60 August 1980 © BYTE Publications Inc system. In applications where disk come from RPS (rotational postion­ because twice the amount of data can storage is a key element, the pro­ ing sensing), which frees the disk con­ be read or written without moving cessor is often disk-IIO-bound. Pro­ troller and 110 (input! output) chan­ the heads. gram execution speed depends on nel for other work during seek time disk speed. Every increase in (head actuator movement) and dur­ Comparing the New Hard Disks throughput will improve the total ing part of the rotational delay time. to Floppy-Disk Drives performance. Improvements have also included The current trends toward multi­ Other improvements in throughput new automatic error detection, cor­ terminal ' systems, real-time transac­ performance in disk subsystems have rection, and recovery capabilities tion oriented systems, small business built into disk controllers. systems, and more powerful personal Voice-coil actuators, described in computers for a great variety of ap­ the next section, are common on plications have created a demand for high-performance disk drives. There more on-line data storage. Floppy­ are both linear and rotary voice-coil disk drives and tape cassettes often do positioners. Rotary voice coils not have the required performance typically take up less space, require (access times, throughput, etc), less power, and generate less heat reliability, or capacities. Thus, the than linear voice coils. Stepper need for secondary storage is being motors with band actuators are filled by new, inexpensive, high­ usually used in lower-performance, performance, highly reliable small­ lower-cost disk drives. Many of the disk drives with capacities, speeds, new small drives use brushless DC and reliability close to the very ex­ (direct current) motors with direct pensive drives. These new drives are drive on the platters. Designed as part physically much smaller and more of the spindles, these motors are com­ reliable than 14-inch cartridge or pact (about 1 inch high), maintain disk-pack drives. They are aimed in­ speed more accurately, use less itially at a gap between floppy drives power, and require simpler power and 14-inch drives (eg: Winchester, supplies than AC (alternating cur­ 5440 cartridges and 3330 type packs). rent) motors with belt drives.
Load more

Recommended publications
  • 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]
  • S-100 Bus Handbook by Dave Bursky
    THE S-100 BUS HANDBOOK THE S-100 BUS HANDBOOK DAVE BURSKY 11 HAYDEN BOOK COMPANY, INC. Rochelle Park, New Jersey Dedication I would like to thank the many friends that helped me to complete this book. Many thanks to Jeff Bierman and Robert Meehan for some of the photographs, and to Katherine Berger, Clare Bursky, and Hilary Mendelson for their typing and proofreading. I am also grateful for the encouragement of others too numerous to name. Additionally, I would like to thank the many manufacturers that loaned various pieces of S-100 bus equipment to me for use in preparing the book. Some of the many companies include: AP Products, Advanced Micro Devices, Ball Brothers Research, Circuit Stik (now part of Bishop Graphics), Continental Specialties, E & L Instruments, EMM Semiconductor, Extensys Corp., Intel Corp., MITS (now part of Pertec Computer Corp.), Motorola, National Semiconductor, NEC Micro- computers, Oliver Audio Engineering, Seals Electronics, Shugart, Solid-State Music (now called SSM), Southwest Technical Products, Technical Design Labs (now called Xitan Corp.), Texas Instruments, Triple I Corp., Vector Electronics, and Vector Graphic Corp. Library of Congress Cataloging in Publication Data Bursky, Dave. The S- 100 bus handbook. Includes index. 1. Microcomputers . 2. Microcomputers-Buses. 1. Title. TK7888.3.B84 621.3819 '58'3 79-26153 ISBN 0-8104-0897-X Copyright © 1980 by HAYDEN BOOK COMPANY, INC. All rights reserved. No part of this book may be reprinted, or reproduced, or utilized in any form or by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying and recording, or in any infor- mation storage and retrieval system, without permission in writing from the Publisher.
    [Show full text]
  • XL Distributed Processing Systems General Information
    XL Distributed Processing Systems SYSTEms General Information XL40 Distributed Processing System XL Distributed Processing Systems General Information SYSTEmS August 1980 680192-000-05 © 1980, Pertee Computer Corporation This document contains the latest information available at the time of publication. How­ ever, Pertec Computer Corporation reserves the right to modify or revise its contents. To ensure that you have the most recent ip.formation, contact your local sales representative. i CONTENTS Page I. INTRODUCTION . 1 II. SYSTEM DESCRIPTION ........................................... '.' 3 CAPABILITIES/FEATURES SUMMARY ................................ 3 Major Capabilities .................................................. 3 Data Retrieval Features .............................................. 5 Data Entry Features ................................................. 6 Programming Features ............................................... 7 Supervisor Features and Utilities ....................................... 8 HARDWARE ..................................................... 10 Micro Control Unit ................................................. 10 Executive Processor ................................................ 10 System Memory ...... " ............................................ 13 Terminals ............. '" . 13 Expansion Cabinets ................................................ 14 Magnetic Tape Drives .......................................... ~ .... 14 Disk Drives ....................................................... 14 Diskette
    [Show full text]
  • Pertec XL40 and XL50 Distributed Processing Systems
    C21-684-101 Distributed PrQcessing & Intelligent Terminals Pertec XL40 and XL50 Distributed Processing Systems The two current members of Pertec's XL Distributed Processing family. The XL40 supports up to 80MB of fixed disk storage and 2.2MB of diskette-based stor­ age. and provides support for up to 16 workstations. The newer XL50 is available in two models. Model 4050-1 has a system memory of up to 512K bytes. and provides support for one or two diskette drives. 10MB or 20MB hard disk drives. and up to 32 workstations. Model 4050-2 also has a system memory of up to 512K bytes. and provides support for one or two 70MB large capacity hard disk drives as well as up to 32 workstations. Purchase prices for the XL40 range from $22.812 to $74.878. Prices for the XL50 range from $24.648 to $86.988. CHARACTERISTICS VENDOR: Pertec Computer Corporation, 17112 Armstrong Avenue, Irvine, California 92714. Tele-phone (714) 540-8340. The XL50 is available in two models and can be configured with DATE OF ANNOUNCEMENT: November 1976. up to 32 terminals. Maximum system memoryfor both models is 512K bytes. DATE OF FIRST DELIVERY: November 1976. MANAGEMENT SUMMARY NUMBER DELIVERED TO DATE: Information not available. Pertec's XL40 and XL50 constitute the XL Distributed SERVICED BY: Pertec Computer Corporation. Processing System. Introduced in 1976 and enhanced in 1979, the XL40 supports up to 80 megabytes of fixed disk CONFIGURATION storage and 2.2 megabytes of diskette-based storage. It can handle from one to 16 operator terminals. The XL40 The XL40 system consists of a system processor, micro­ peripheral processor and memory, from one to three can be arranged as a standalone system with mUltiple magnetic tape drives, from one to four disk drives, from one local workstations or it can be set up in a network of to 16 operator terminals, from one to 16 station printers, and terminals and station printers accessing a local XL40 over an optional communications processor, line printer, dial-up or leased telephone lines.
    [Show full text]
  • CMC 3/5 Keyprocessing ® Systems General Information
    CMC 3/5 KeyProcessing ® Systems '-, General Information CMC 3/5 KeyProcessing ® Systems Genera I Information july 1977 Printed in U.S.A. 680277 © 1977, CMC, a division of Pertec Computer Corporation This document contains the latest information available at the time of pUblication. However, CMC, a division of Pertec Computer Corpo­ ration reserves the right to modify or revise its contents. To ensure that you have the most recent information, contact your local ('Me representative. ii CONTENTS Page SYSTEM OVERVIEW ............................................. 1 APPLICATIONS OVERVIEW....................................... 2 H.I\RDWARE ................................................... 3 KEYSTATIONS ............................................... 3 SUPERVISORY CONSOLE ...................................... 4 Control Panel . .. 4 Computer .................................................. 4 Magnetic Disk Unit ........................................... 4 Magnetic Tape Units .......................................... 5 DUPLEX CONTROL UNIT ...................................... 5 TELEPRINTER ............................................... 5 LINE PRINTER ............................................... 5 DATA COMMUNICATIONS ...................................... 6 TeleBatch™ Data Communications System ........................ 6 SYSTEM FUNCTIONS ............................................ 6 FORMATTING ................................................ 7 DATA ENTRy ................................................ 8 DATA VERIFICATION AND BACKGROUND
    [Show full text]
  • Hardware and Peripherals
    Part V Bits and Bytes. 17/1 17/2 Part V Bits and Bytes Blank page. Chapter 17 Hardware and Peripherals 17.1 ... Memory The microprocessor was a significant key to lowering the cost of the personal computer. However the other key and an equally important one was low-cost semiconductor memory. Semiconductor memory started replacing magnetic core memory around 1967. Their are two types of semiconductor Random Access Memory (RAM). Dynamic RAM (DRAM) requires periodic refresh of the memory contents and Static RAM (SRAM) retains the contents without refresh. Both types of RAM loose their contents when the power is turned off. Read only memory (ROM) retains its contents once it is programmed, even when the power is turned off. The first commercial 1K metal oxide semiconductor DRAM was the Intel 1103 released in October 1970. This chip had a pivotal role in undercutting the price and replacement of core memory. Intel continued to improve DRAM capacities with the release of the 4K 2107 chip in 1972 and the 16K 2117 chip in 1977. However, competitive challenges from Japanese companies, would have a significant impact on Intel and other North American producers of memory chips. Japan decided to make a strategic investment in the semiconductor memory industry around in the late 1970’s. The effect of this was the first open market release of a 64K DRAM chip by Fujitsu Limited in 1979, and introduction of the first 1-megabit DRAM chip by the Toshiba Corporation in 1985. A number of other factors contributed to the dominance of Japanese manufacturers in the 1980’s.
    [Show full text]
  • Single Chip Microcomputer Mos Sc/Mp Now Offered Gi
    ROC DIGEST Volume 3, Number 7 January/February, 1977 SINGLE CHIP MICROCOMPUTER MOS SC/MP NOW OFFERED Samples are now available of a new N-chan­ nel MOS version of the "SC/MP" 8-bit single­ chip microprocessor that is twice as fast and uses only one-fourth as much power as the P­ channel version. Power consumption of SC/MP-ll is less than 200 mW, and only a single +5 V supply is re- quired. (Cont'd on page 9) GI & ITT SIGN 6100 PACT General Instrument and ITT have signed a licence agreement for ITT to second source GI's 16-bit microprocessor, the CP6100. GI will provide ITT with masks, hardware, and software knowledge. There will be no payment of money or transfer of technology from ITT to GI. However, a provision for future ex­ The 8048 single-chip microcomputer has change of technical improvements developed been introduced by Intel Corp. 's Microcom­ by either company relating to the 1600 and puter Systems Division. The new microcomputer relevant software was spelled out. is one of three single-chip systems compris­ ITT will produce the CPU at its Intermetall ing the MCS-48 Microcomputer Systems family, operation in Freiburg, Germany. with a series of MCS-48 peripherals and a line of programming and product development tools. Intel plans to supply samples early PROCESS CONTROL INDUSTRY REPORT 1977 and to begin production deliveries in The process control industry is eager to the spring. tap new, sophisticated types of analytical The Intel 8048 and the 8748, a programm­ instruments--Fourier Transform Infrared, Mass able version of the new microcomputer, are Spectrometry, Microwave Rotation 1 Spectrome­ the first general-purpose digital processing try, and Raman Spectrophometry--for on-line and control systems to be integrated into a control applications, but their high cost has single chip of semiconductor material., An deterred widespread use.
    [Show full text]
  • 8800Bdm-Sm.Pdf
    BiwramiM a subsidiary of Pertoc Computer Corporation 2450 Alamo S.E. /Albuquerque, New Mexico 87106 NOTICE Information contained within this document may not be reproduced, distributed or dis- closed in full or in part by any person without prior approval of Pertec Computer Corporation, Microsystems Division. Marketing Headquarters Pertec Computer Corporation Microsystems Division 20630 Nordhoff Street Chatsworth, CA 91311 Phone (213) 998-1800 TWX (910) 494-2788 International Marketing Headquarters Pertec Computer Corporation Business Systems Division 17112 Armstrong Avenue Irvine, CA 92714, USA Phone (714) 540-8340 TWX (910) 595-1912 ii CHANGE RECORD Revision Date Pages * A June, 1978 Initial Release m - • TABLE OF CONTENTS Section £M£ Part I. Introduction and Operator's Guide 1. Introduction to This Manual . 3 2. Introduction to the Standard System 4 3. Using This Documentation Package 10 Part II. 8800b Turnkey Computer 1. Introduction 15 2. Theory of Operation 21 2-1. General 23 2-2. CPU Board .26 2-3. Turnkey Module .29 3. Advanced Operations 37 3-1. The Front Panel 39 3-2. The Turnkey Module 40 3-3. AUTO-START 54 3-4. Miscellaneous Options 55 3-5. The Power Supply 57 4. Troubleshooting Hints 59 4-1. Introduction 61 4-2. Preliminary Considerations 61 4-3. CPU 62 4-4. Turnkey Module 62 Part III. Minidisk System 1. Introduction 67 1-1. MITS Altair Minidisk System Description ... 69 1-2. Specifications 69 2. Theory of Operation 73 2-1. General 75 2-2. Logic Circuits 75 2-3. Schematic Referencing 75 2-4. Minidisk Block Diagram 80 2-5.
    [Show full text]
  • In the Beginning... a Legacy of Computing at Marshall University Jack L
    Marshall University Marshall Digital Scholar Manuscripts Library Special Collections Spring 2018 In the Beginning... A Legacy of Computing at Marshall University Jack L. Dickinson Marshall University, [email protected] Arnold R. Miller Ed.E Marshall University, [email protected] Follow this and additional works at: http://mds.marshall.edu/lib_manu Part of the History of Science, Technology, and Medicine Commons, Library and Information Science Commons, Other Computer Sciences Commons, Other History Commons, and the United States History Commons Recommended Citation Dickinson, Jack L., and Arnold R. Miller. In the Beginning…A Legacy of Computing at Marshall University : A brief history of the early computing technology at Marshall University, Huntington, W.Va., in the forty years: 1959-1999. Huntington, Marshall University Libraries, 2018. This Personal Paper is brought to you for free and open access by the Library Special Collections at Marshall Digital Scholar. It has been accepted for inclusion in Manuscripts by an authorized administrator of Marshall Digital Scholar. For more information, please contact [email protected], [email protected]. In the Beginning… A Legacy of Computing at Marshall University A brief history of the early computing technology at Marshall University, Huntington, W.Va., in the forty years: 1959-1999. Jack L. Dickinson, Marshall Special Collections Dept. Dr. Arnold R. Miller, Ed.D., Emeritus Vice President, Information Technology Spring 2018 COPYRIGHT © 2018 The Marshall University Libraries Huntington, W.Va. www.marshall.edu All rights reserved. No part of this book may be copied or reproduced without permission of the publisher. ISBN13: 978-0-9903359-2-4 The British Bombe 1942 NOTES TO THE READER: If you consider yourself somewhat technically challenged, or simply are not interested in the “bits and bytes, speeds and feeds,” then just skip the second part of each section titled “Hardware and Software.” Images that appear in this work that are captioned as “stock images” were from various websites.
    [Show full text]
  • Chapter 4 Transition to Microcomputers
    Chapter 4 Transition to Microcomputers The 1970’s were a period of transition for personal computing. There was a change from the common usage of time sharing on large computers to the use of low-cost personal computers. This cost aspect changed our general understanding of what defined a computer as being personal. Previously the definition only required that a computer be designed for use by a single person, such as those developed by DEC, IBM and MIT in the 1960’s. During the 1970’s, the definition evolved to include a price level that was affordable to the average consumer. This change became possible by a period of hardware transition. The microprocessor and memory chips replaced discrete components and core memory. This reduced the complexity and cost of building a personal computer. Then factory-built “turn-key” units changed the market from the computer hobbyist and software enthusiast to the “appliance user” and a larger consumer market. This was also a decade in which the main computer companies failed to develop personal computer products for the consumer market. Intel created systems for software development. However, they did not extend these products into a consumer computer. Digital Equipment Corporation (DEC) could also have adapted their PDP-8 and LSI-11 designs to a consumer product. A product was proposed by an employee David Ahl, but rejected by the company. Hewlett-Packard also rejected an offer by Stephen Wozniak to market what became the highly successful Apple II computer. Federal antitrust actions discouraged IBM from any product line expansion during the 1970's.
    [Show full text]
  • Computer Notes Votume3 )Ssue7 @1978 PERTEC COMPUTER CORPORAHON 20630 Nordhoff Street Chatsworth, CA 91311 (213) 998-1800
    / \ computer notes Votume3 )ssue7 @1978 PERTEC COMPUTER CORPORAHON 20630 Nordhoff Street Chatsworth, CA 91311 (213) 998-1800 Editor: Marsha Sutton Voiume 3, issue 7, January/ February 1978 Products or services, other than those of PERTEC COMPUTER CORPORATION, advertised in Computer Notes magazine are not necessarily endorsed by PERTEC COMPUTER CORPORATION, thereby relieving itself of all legal responsibility. Computer Notes Jan/Feb 1978 !n This issue The Latest with CN System Timing Modification for the M!TS/Altair88-DCDD Floppy Disk. 4 by Tom Durston A. Copy/Rewrite Procedure 4 Computer Notes is changing. by Gale Schonfeld The top news for this issue is to announce the compietion B. Single Drive BASIC Diskette Rewrite Procedure 5 of the eventfui reiocation of the Computer Notes editoriai by Charles Vertrees office. The office has been moved from MiTS @ in C. Single Drive DOS Diskette Rewrite Procedure 6 Aibuquerque to PERTEC COMPUTER CORPORATiON in byDrewEinhorn California. And to occupy this newiy located office is a completely new editoriai staff — mysetf. My name is Marsha D. Easy Floppy Disk Alignment Check 6 by Tom Durston Sutton, and I am the new editor of Computer Notes. The address of the new office can be found on the inside front Mce on the KCACR 7 cover. by Doug Jones Severai further changes wit! be forthcoming, of which you Union County Career Center, Update 1977 9 byJamesGupton.Jr. should take note. Computer Notes will continue to sell for 50% a copy, but it wiil be published every other month, MITS/Altair CPU Modification 11 rather than monthiy. Subscriptions wiii now be $2.50 a year byDarreiVanBuer and $5.00 for two years.
    [Show full text]
  • Chapter 6 Microsoft in the 1970'S
    Chapter 6 Microsoft in the 1970's 6.1 ... Gates/Allen Early Years William Henry Gates was born on the 28th. of October 1955 in Seattle, Washington. He was the only son and the second of three children by William and Mary Gates. The father was a prominent Seattle lawyer and the mother was active in community organizations such as the United Way. Bill's parents enrolled him in Seattle's exclusive Lakeside School in 1967. This was a progressive private all male school with a disciplined approach to education. During the 1967/68 school year, the teaching staff recommended acquisition of computer facilities to expose the students to the technology. The school could not afford to purchase a computer. However the Lakeside Mothers Club agreed to finance the use of a time sharing service. In 1968 the school obtained an ASR-33 Teletype terminal and used a local access line to dial into a General Electric Mark II time sharing system. In his 1968/69 school year at the age of thirteen, Bill Gates started programming. Another student interested in programming was Paul G. Allen, who was born in 1953. From their mutual enthusiasm for programming computers a friendship developed which continued through high-school and university. It is this association that eventually led to their founding of Microsoft. 6/1 6/2 Part II 1970’s – The Altair/Apple era Figure 6.1: Paul Allen and Bill Gates (standing) at the Lakeside School computer room teletype terminal, c1968. Photograph is courtesy of Microsoft Corporation. The students’ enthusiasm for programming quickly strained the schools' time sharing budget.
    [Show full text]