History of Computers PDF

Summary

This document provides a brief history of computers, starting from their primitive designs in the early 19th century to the powerful machines of today. It highlights key figures and milestones in computer development.

Full Transcript

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 Lesson HISTORYOFCOMPUTERS:ABRIEF
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TIMELIN
The history of computers began with primitive designs in the early 19th century and
went on to change the world during the 20th century.

(Imagecredit:Getty/Science&SocietyPictureLibrary)

The history of computers goes back over 200 years. At first theorized by
mathematicians and entrepreneurs, during the 19th century mechanical calculating machines
were designed and built to solve the increasingly complex number- crunching challenges.
The advancement of technology enabled ever more-complex computers by the early 20th
century, and computers became larger and more powerful.

Today, computers are almost unrecognizable from designs of the 19th century, such
as Charles Babbage's Analytical Engine — or even from the huge computers of the 20th
century that occupied whole rooms, such as the Electronic Numerical Integrator and
Calculator.

Here's a brief history of computers, from their primitive number-crunching
originstothepowerfulmodern-daymachinesthatsurftheInternet,rungamesand stream
multimedia.

19THCENTURY

 1801: Joseph Marie Jacquard, a French merchant and inventor invents a loom that uses
punched wooden cards to automatically weave fabric designs. Early computers would use
similar punch cards.

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 1821: English mathematician Charles Babbage conceives of a steam-driven calculating
machine that would be able to compute tables of numbers. Fundedby the British
government, the project, called the "Difference Engine" fails due to the lack of
technology at the time, according to the University of Minnesota.
 1848: Ada Lovelace, an English mathematician and the daughter of poet Lord Byron,
writes the world's first computer program. According to Anna Siffert, a professor of
theoretical mathematics at the University of Münster in Germany, Lovelace writes the
first program while translating a paper on Babbage's Analytical Engine from French into
English. "She also provides her own comments
onthetext.Herannotations,simplycalled"notes,"turnouttobe three times as long as the
actual transcript," Siffertwrote inan article for TheMax Planck Society. "Lovelace also
adds a step-by-step description for computation of Bernoulli numbers with Babbage's
machine — basically an algorithm — which, in effect, makes her the world's first
computer programmer."
Bernoullinumbersareasequenceofrationalnumbersoftenusedincomputation.

Famed mathematician Charles Babbage designed a Victorian-era computer
calledtheAnalyticalEngine.Thisisaportionofthemillwithaprintingmechanism.(Imagecredit:
Getty / Science & Society Picture Library)

 1853: Swedish inventor Per Georg Scheutz and his son Edvard design the world's first
printing calculator. The machine is significant for being the first to "compute tabular
differences and print the results," according to Uta C. Merzbach's book, "Georg Scheutz
and the First Printing Calculator"(Smithsonian Institution Press, 1977).
 1890:HermanHollerithdesignsapunch-cardsystemtohelpcalculatethe1890
U.S. Census. The machine,saves the government several years of calculations,
andtheU.S.taxpayer approximately $5million,according to ColumbiaUniversityHollerith
later establishes a company that will eventually become International Business Machines
Corporation (IBM).

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 EARLY20THCENTURY

 1931: At the Massachusetts Institute of Technology (MIT), Vannevar Bush invents and
builds the Differential Analyzer, the first large-scale automatic general-purpose
mechanical analog computer, according to Stanford University.
 1936: Alan Turing, a British scientist and mathematician, presents the principleof a
universal machine, later called the Turing machine, in a paper called "On Computable
Numbers…" according to Chris Bernhardt's book "Turing's Vision" (The MIT Press,
2017). Turing machines are capable of computing anything that is computable. The
central concept of the modern computer is based on his ideas. Turing is later involved in
the development of the Turing-Welchman Bombe, an electro-mechanical device
designed to decipher Nazi codes during World War II, according to the UK's National
Museum of Computing.
 1937: John Vincent Atanasoff, a professor of physics and mathematicsat Iowa State
University, submits a grant proposal to build the first electric-onlycomputer, without
using gears, cams, belts or shafts.

The newly renovated garage where in 1939 Bill Hewlett and Dave Packard
startedtheirbusiness,HewlettPackard,inPaloAlto,California.(Imagecredit:Getty/DavidPaul
Morris)

 1939: David Packard and Bill Hewlett found the Hewlett Packard Company in Palo Alto,
California. The pair decide the name of their new company by the toss of a coin, and
Hewlett-Packard's first headquarters are in Packard's garage, according to MIT.
 1941: German inventor and engineer Konrad Zuse completes his Z3 machine, the
world's earliest digital computer, according to Gerard O'Regan's book "ABrief History of
Computing" (Springer, 2021). The machine was destroyed during a bombing raid on
Berlin during World War II. Zuse fled the German capital after

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 thedefeatof Nazi Germanyandlaterreleased the world's first commercial digital computer,
the Z4, in 1950, according to O'Regan.
 1941: Atanasoff and his graduate student, Clifford Berry, design the first digital
electroniccomputerintheU.S.,calledtheAtanasoff-BerryComputer(ABC). This marks the
first time a computer is able to store information on its main memory, and is capable of
performing one operation every 15 seconds, according to the book "Birthing the
Computer" (Cambridge Scholars Publishing, 2016)
 1945: Two professors at the University of Pennsylvania, John Mauchly and J. Presper
Eckert, design and build the Electronic Numerical Integrator and Calculator (ENIAC).
The machine is the first "automatic, general-purpose, electronic, decimal, digital
computer," according to Edwin D. Reilly's book "Milestones in Computer Science and
Information Technology" (Greenwood Press, 2003).

Computer operators program the ENIAC, the first automatic, general-
purpose,electronic,decimal,digitalcomputercomputer,bypluggingandunpluggingcablesand
adjusting switches (Image credit: Getty / Historical)

 1946: Mauchly and Presper leave the University of Pennsylvania and receive funding
from the Census Bureau to build the UNIVAC, the first commercial computer for
business and government applications.
 1947: William Shockley, John Bardeen and Walter Brattain of Bell Laboratories invent
the transistor. They discover how to make an electric switch with solid materials and
without the need for a vacuum.
 1949: A team at the University of Cambridge develops the Electronic Delay Storage
Automatic Calculator (EDSAC), "the first practical stored-program computer," according
to O'Regan. "EDSAC ran its first program in May 1949 when it calculated a table of
squares and a list of prime numbers," O'Regan wrote. In November 1949, scientists with
the Council of Scientific and Industrial
Research(CSIR),nowcalledCSIRO,buildAustralia'sfirstdigitalcomputer

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 called the Council for Scientific and Industrial Research Automatic Computer
(CSIRAC). CSIRAC is the first digital computer in the world to play music, according to
O'Regan.

LATE20THCENTURY
 1953: Grace Hopperdevelops the first computer language, which eventually becomes
known as COBOL, which stands for COmmon, Business-Oriented Language according
to the National Museum of American History. Hopper islater dubbed the "First Lady of
Software" in her posthumous Presidential Medalof Freedom citation. Thomas Johnson
Watson Jr., son of IBM CEO Thomas Johnson Watson Sr., conceives the IBM 701
EDPM to help the United Nations keep tabs on Korea during the war.
 1954: John Backus and his team of programmers at IBM publish a paper describing
their newly created FORTRAN programming language, an acronym for FORmula
TRANslation, according to MIT.
 1958: Jack Kilby and Robert Noyce unveil the integrated circuit, known as the computer
chip. Kilby is later awarded the Nobel Prize in Physicsfor his work.
 1968: Douglas Engelbart reveals a prototype of the modern computer at the Fall Joint
Computer Conference, San Francisco. His presentation, called "AResearch Center for
Augmenting Human Intellect" includes a live demonstration of his computer, including a
mouse and a graphical user interface (GUI), according to the Doug Engelbart Institute.
This marks the development of the computerfrom a specialized machine for academics
to a technology that is more accessible to the general public.

The first computer mouse was invented in 1963 by Douglas C. Engelbart
andpresentedattheFallJointComputerConferencein1968(Imagecredit:Getty/Apic)

 1969: Ken Thompson, Dennis Ritchie and a group of other developers at Bell Labs
produce UNIX,an operating system that made "large-scale networking of

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 diverse computing systems — and the internet — practical," according to BellLabs.. The
team behind UNIX continued to develop the operating system using the C
programming language, which they also optimized.
 1970: The newly formed Intel unveils the Intel 1103, the first Dynamic Access Memory
(DRAM) chip.
 1971: A team of IBM engineers led by Alan Shugart invents the "floppy disk," enabling
data to be shared among different computers.
 1972: Ralph Baer, a German-American engineer, releases Magnavox Odyssey,
theworld'sfirsthomegameconsole,inSeptember1972,accordingto the Computer Museum
of America. Months later, entrepreneur Nolan Bushnell and engineer Al Alcorn with
Atari release Pong, the world's first commercially successful video game.
 1973: Robert Metcalfe, a member of the research staff for Xerox, develops Ethernet for
connecting multiple computers and other hardware.
 1977: The Commodore Personal Electronic Transactor (PET), is released onto the home
computer market, featuring an MOS Technology 8-bit 6502 microprocessor, which
controls the screen, keyboard and cassette player. The PET is especially successful in the
education market, according to O'Regan.
 1975: The magazine cover of the January issue of "Popular Electronics"
highlightstheAltair8080 asthe"world'sfirst minicomputerkit to rival commercial models."
After seeing the magazine issue, two "computer geeks," Paul Allen and Bill Gates, offer to
write software for the Altair, using the new BASIC language. OnApril 4,afterthesuccess
ofthisfirst endeavor, thetwo childhood friendsform their own software company,
Microsoft.
 1976: Steve Jobsand Steve Wozniak co-found Apple Computer on April Fool's Day.
They unveil Apple I, the first computer with a single-circuit board and ROM (Read Only
Memory), according to MIT.

TheAppleIcomputer,devisedbySteveWozniak,StevenJobsandRonWayne,was a basic
circuit board to which enthusiasts would add display units andkeyboards. (Image credit:
Getty / Science & Society Picture Library)

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 1977: Radio Shack began its initial production run of 3,000 TRS-80 Model 1 computers
— disparagingly known as the "Trash 80" — priced at $599,according to the National
Museum of American History. Within a year, the company took 250,000 orders for the
computer, according to the book "HowTRS-
80EnthusiastsHelpedSparkthePCRevolution"(TheSeekerBooks,2007).
 1977: The first West Coast Computer Faire is held in San Francisco. Jobs and Wozniak
present the Apple II computer at the Faire, which includes color graphics and features an
audio cassette drive for storage.
 1978:VisiCalc,thefirstcomputerizedspreadsheetprogramisintroduced.
 1979: MicroPro International, founded by software engineer Seymour Rubenstein,
releases WordStar, the world's first commercially successful word processor. WordStar is
programmed by Rob Barnaby, and includes 137,000lines of code, according to Matthew
G. Kirschenbaum's book "Track Changes: ALiterary History of Word Processing"
(Harvard University Press, 2016).
 1981: "Acorn," IBM's first personal computer, is released onto the market at a price point
of $1,565, according to IBM. Acorn uses the MS-DOS operating system from Windows.
Optional features include a display, printer, two diskette drives, extra memory, a game
adapter and more.

TheAcornwasIBM'sfirstpersonalcomputerandusedMS-DOSoperatingsystem. (Image
credit: Getty / Spencer Grant)

 1983: The Apple Lisa, standing for "Local Integrated Software Architecture" but also the
name of Steve Jobs' daughter, according to the National Museum of American History
(NMAH), is the first personal computer to feature a GUI. The machine also includes a
drop-down menu and icons. Also this year, the Gavilan SC is released and is the first
portable computer with a flip-form design and the very first to be sold as a "laptop."

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 1984: The Apple Macintosh is announced to the world during a Superbowl
advertisement.TheMacintoshislaunchedwitharetailpriceof$2,500,according to the
NMAH.
 1985: As a response to the Apple Lisa's GUI, Microsoft releases Windows in November
1985, theGuardianreported. Meanwhile, Commodore announces the Amiga 1000.
 1989: Tim Berners-Lee, a British researcher at the European Organization for Nuclear
Research (CERN), submits his proposalfor what would become the World Wide Web.
His paper details his ideas for Hyper Text Markup Language (HTML), the building
blocks of the Web.
 1993: The Pentium microprocessor advances the use of graphics and music on PCs.
 1996:SergeyBrinandLarryPagedeveloptheGooglesearchengineatStanford University.
 1997: Microsoft invests $150 million in Apple, which at the time is struggling
financially.This investment ends an ongoing court case in which Apple accused
Microsoft of copying its operating system.
 1999: Wi-Fi, the abbreviated term for "wireless fidelity" is developed, initially covering a
distance of up to 300 feet (91 meters) Wired reported.

21stCENTURY

 2001: Mac OS X, later renamed OS X then simply macOS, is released by Apple as the
successor to its standard Mac Operating System. OS X goes through 16 different
versions, each with "10" as its title, and the first nine iterations are nicknamed after big
cats, with the first being codenamed "Cheetah," TechRadarreported.
 2003: AMD's Athlon 64, the first 64-bit processor for personal computers, is released to
customers.
 2004:The Mozilla Corporation launches Mozilla Firefox 1.0. The Web browser is oneof
the first major challenges to Internet Explorer, owned byMicrosoft. During its first five
years, Firefox exceeded a billion downloads by users, according to the Web Design
Museum.
 2005:GooglebuysAndroid,aLinux-basedmobilephoneoperatingsystem
 2006: The MacBook Pro from Apple hits the shelves. The Pro is the company's first Intel
-based, dual-core mobile computer.
 2009: Microsoft launches Windows 7 on July 22. The new operating system features the
ability to pin applications to the taskbar, scatter windows away by shaking another
window, easy-to-access jumplists, easier previews of tiles and more, TechRadar reported.

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 AppleCEOSteveJobsholdstheiPadduringthelaunchofApple'snewtabletcomputing device in
San Francisco, 2010. (Image credit: Getty)

 2010:TheiPad,Apple'sflagshiphandheldtablet,isunveiled.
 2011:GooglereleasestheChromebook,whichrunsonGoogleChromeOS.
 2015:ApplereleasestheAppleWatch.MicrosoftreleasesWindows10.
 2016: The first reprogrammable quantum computerwas created. "Until now, there hasn't
been any quantum-computing platform that had the capability to program new
algorithms into their system. They're usually each tailored to attack a particular
algorithm," said study lead author Shantanu Debnath, a quantum physicist and optical
engineer at the University of Maryland, College Park.
 2017:TheDefenseAdvancedResearchProjectsAgency(DARPA)isdeveloping a new
"Molecular Informatics" program that uses molecules as computers. "Chemistry offers a
rich set of properties that we may be able to harness for rapid, scalable information
storage and processing," Anne Fischer, program manager in DARPA's Defense Sciences
Office, said in a statement. "Millions of molecules exist, and each molecule has a unique
three-dimensional atomic structure as well as variables such as shape, size, or even color.
This richness provides a vast design space for exploring novel and multi-value ways to
encode and process data beyond the 0s and 1s of current logic-based, digital
architectures."
 2019: A team at Google became the first to demonstrate quantum supremacy— creating
a quantum computer that could feasibly outperform the most powerful classical
computer — albeit for a very specific problem with no practical real- world application.
The described the computer, dubbed "Sycamore" in a paper that same year in the
journal Nature. Achieving quantum advantage – in which a quantum computer solves a
problem with real-world applications faster than the most powerful classical computer
—is still a ways off.
 2022: The first exascale supercomputer, and the world's fastest, Frontier, went
onlineattheOakRidgeLeadershipComputingFacility(OLCF)inTennessee.
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Built by Hewlett Packard Enterprise (HPE) at the cost of $600 million, Frontier uses
nearly 10,000 AMD EPYC 7453 64-core CPUs alongside nearly 40,000 AMD Radeon
Instinct MI250X GPUs. This machine ushered in the era of exascale computing, which
refers to systems that can reach more than one exaFLOP of power – used to measure the
performance of a system. Only one machine– Frontier–is
currentlycapableofreachingsuchlevels ofperformance. It is currently being used as a tool
to aid scientific discovery.

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 Lesson AHISTORYOFEDUCATION
2 TECHNOLOG
This article is an abstract from Dr. Maryanne Berry’s Sonoma State University
EDCT 552 Praxis Course.

Watching the NY Times timeline “The Evolution of Classroom Technology” was a
good look at how far classroom technology has come and what was
considered“technology.”The“Hornbook”andthe“Pointer”lookedmorelike thetools of corporal
punishment rather than teaching aids. The progression of the “Magic Lantern;”tothe“iPad”
wasagreat timelineofthe“visual”aidsusedintheclassroom. These devices eventually led to the
PowerPoint and now on to the Infographic.

Early20thCenturyClassroom

Russell’s “A Brief History of Technology in Education” was the narrative for the NY
Times “Timeline” graphic. For the most part I would agree with his observation,
“Today,mostpeopleassociate“educationaltechnology”with computers and the Internet,”
however in America’s primary and secondary schools educational technology encompasses
much more than computers and has roots that extendback several centuries. Blackboards and
books are now taken for granted and are assumed to be part of every student’s educational
experience. In their day, these “technologies” were viewed as radical and revolutionary
teaching and learning tools. (Russell, 2006, p.137)

In 1806, students would use a desktop sandbox to practice the alphabet. After the
children had made each of the letters, the monitor smoothed the sand witha flat iron and a
new letter was presented” (Gutek, 1986, p. 62). Considered “a new form of education
technology” (Russell, 2006, p.137) one of the earliest forms of teaching technology was
images that were drawn in the sand.

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 Aftergoing through most of thedevices that were presented in the NY Times
“Timeline” Russell finishes his article with computers as the most current “new” educational
technology by stating, “While there are many more examples of computer-based tools that
are used in today’s classrooms, there is no question that computers are the most recent
technology that has penetrated the American educational system. However, an important
question that remains largely unanswered focuses on how computer use in schools is affecting
teaching and learning” (Russell, 2006, p.152). Good question, but since computers offer so
much in the way of education, I think computers are the best thing to happen in the
classroom since the blackboard.

I want to include the Cuban and Strudler quotes as they put a contemporary spin on
the evolution of education technology. “I predict that the slow revolution in technology
access, fueled by popular support and continuing as long as there is economic prosperity, will
eventually yield exactly what the promoters have sought: every student, like every worker,
will eventually have a personal computer. But no fundamental change in teaching practices
will occur;” (Larry Cuban – Stanford) and “Nearlytheentirefieldoftechnologyandeducationis
aboutchangein someway. It’s about the dreams of what could be, the realities of what is, and
the efforts to whittle away at the gap between the two.” (Neal Strudler – UNLV)

TECHNOLOGYINEDUCATION

OneRoomSchoolhouse

The first American schools were one-room cabins, the mission of which was to
produce literate and moral citizens. Students attended school for between one and six months
a year and there were few educational tools available. But as increasing numbers of American
communities were settled the education system became more firmly established. To aid the
learning process, educational technologies, such as slates, hornbooks, blackboards, and books
were introduced.

Although technologies like the blackboard and books are now taken
forgrantedandareassumedto bepartof every student’s educationalexperience,these

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technologies were viewed as radical teaching tools when they were first introduced.
Overtime,avarietyoftechnologiessuchasfilm,radio,television,teachingmachines,
microcomputers and the Internet have been introduced to schools, each sparking controversy
about its usefulness for schooling and effectiveness as a teaching and learning aid.

THEHORNBOOKANDPRINTEDBOOKS

Hornbook

Johannes Gutenberg began building a primitive version of the printing press in 1436
and the first Gutenberg Bible was printed in 1455 (de la Mare, 1997). Nearly two centuries
later Stephen Dayne brought the first printing press used in the United States(Rubinstein,
1999). However, since theywere expensive and were not readily available, books were not
commonly used in the early years of American schooling.

In lieu of printed books, American settlers improvised with a device known as the
hornbook. Adopted from England, the hornbook was one of the first forms of educational
technology used to aid in teaching reading in American schools. A hornbook was “a small,
wooden, paddle-shaped instrument. A sheet of paper, with the alphabet, numerals, theLord’s
Prayer, and other reading matter printed on it was pasted upon the blade and the entire
implement was covered with sheets of transparent horn” (Good & Teller, 1973, p. 28). The
hornbook was a crude, low-cost solution to the American settler’s problem of how to teach
children to read without having books available. Although it was useful at the time, the
hornbook became obsolete as the cost of printing decreased and texts became more widely
available.

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 EarlySchoolBook

Johannes Gutenberg began building a primitive version of the printing press in 1436
and the first Gutenberg Bible was printed in 1455 (de la Mare, 1997). Nearly two centuries
later Stephen Dayne brought the first printing press used in the United States(Rubinstein,
1999). However, since they were expensive and were not readily available, books were not
commonly used in the early years of American schooling.

In lieu of printed books, American settlers improvised with a device known as the
hornbook. Adopted from England, the hornbook was one of the first forms of educational
technology used to aid in teaching reading in American schools. A hornbook was “a small,
wooden, paddle-shaped instrument. A sheet of paper, with the alphabet, numerals, theLord’s
Prayer, and other reading matter printed on it was pasted upon the blade and the entire
implement was covered with sheets of transparent horn” (Good & Teller, 1973, p. 28). The
hornbook was a crude, low-cost solution to the American settler’s problem of how to teach
children to read without having books available. Although it was useful at the time, the
hornbook became obsolete as the cost of printing decreased and texts became more widely
available.

THESANDBOX

Early20thCenturyClassroom

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 Johannes Gutenberg began building a primitive version of the printing press in 1436
and the first Gutenberg Bible was printed in 1455 (de la Mare, 1997). Nearly two centuries
later Stephen Dayne brought the first printing press used in the United States(Rubinstein,
1999). However, since they were expensive and were not readily available, books were not
commonly used in the early years of American schooling.

In lieu of printed books, American settlers improvised with a device known as the
hornbook. Adopted from England, the hornbook was one of the first forms of educational
technology used to aid in teaching reading in American schools. A hornbook was “a small,
wooden, paddle-shaped instrument. A sheet of paper, with the alphabet, numerals, theLord’s
Prayer, and other reading matter printed on it was pasted upon the blade and the entire
implement was covered with sheets of transparent horn” (Good & Teller, 1973, p. 28). The
hornbook was a crude, low-cost solution to the American settler’s problem of how to teach
children to read without having books available. Although it was useful at the time, the
hornbook became obsolete as the cost of printing decreased and texts became more widely
available.

THEBLACKBOARD

SlateTablet

While individual slates were used in classrooms during the early 1800s, it was not until
1841 that the classroom chalkboard was first introduced. Shortly thereafter, Horace Mann
began encouraging communities to buy chalkboards for their classrooms. By the late 1800s,
the chalkboard had become a permanent fixture in most classrooms.

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 Blackboard

As with many forms of educational technology, learning how to integrate the
chalkboard into classroom instruction was not an easy task. As Shade (2001) explains, “When
first introduced, the chalkboard went unused for many years until teachers realized that it
could be used for whole group instruction. They had to change their thinking from individual
slates to classroom slates” (p. 2).

Similar to more modem forms of educational technology, the chalkboard also received
praise from community leaders. As an example, Josiah Bumstead, a Springfield
Massachusetts councilman, said, “The inventor or introducer of the blackboard deserves to
be ranked among the best contributors to learning and science, if not among the greatest
benefactors of mankind” (Daniel, 2000, p. 1). Thinking of the blackboard as a revolutionary
form of educational technology seems counterintuitive. But it is one of the few types of media
that has survived the test of time and is still regularly used in classrooms today.

MAGICLANTERN

MagicLantern

The height of its popularity was around 1870. The predecessor to the slide machine,
the magic lantern projected images on glass plates. By the end of World War I, Chicago’s
public school system had a collection of some 8,000 lantern slides.

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 LEADPENCILS

LeadPencils

Around the turn of the 20thcentury mass produced pencils and paper become readily
available, gradually replacing the school slate.

STEREOSCOPE

Stereoscope

At the turn of the 20thcentury, the Keystone View Company began to market
stereoscopes. The three dimensional devices, which were popular in home parlors, were sold
to schools featuring educational sets containing hundreds of images.

FILM

During the next several decades, the American educational system expanded and
became more developed. The price of producing paper and printing books also dropped to
levels that enabled paper to replace slates and allowed each child tohave his or her own
books. But just as books were becoming widely available to students, a new form of
educational technology began to emerge, namely film.

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 FilmStripProjector

The kinetoscope, which is now known as the motion picture, was invented in 1889.
Over the next decade, film equipment was developed and refined. And in1902, Charles
Urban of London began exhibiting the first educational films. Among these filmswere “slow-
motion, microscopic, and undersea views” and “such subjects as the growth of plants and the
emergence of the butterfly from the chrysalis” (Saettler, 1990, p. 96). In 1911, Thomas
Edison also contributed to the use of film in the classroom by producing a series on the
American Revolution.

With the rapid growth of American schools, both in terms of the number of schools
and the quantity of students attending those schools, there was a pressing need to provide
standard, high-quality instruction to large numbers of students. Atthe time, some proponents
believed that using film in classrooms met this important educational need. As an example,
Thomas Edison proclaimed, “Books will soon be obsolete in the schools. Scholars will soon
be instructed through the eye. It is possible to touch every branch of human knowledge with
the motion picture.” (Saettler, 1990, p. 98)

In 1910, enthusiasm for educational films led Rochester New York’s Board of
Education to adopt education films for instructional use. Many other public school systems
soon followed Rochester’s lead and by 1931 “twenty-five states had units in their departments
of education devoted to films and related media” (Cuban, 1986, p. 12). Edison’s prophecy
and the public school support for educational film spawned a new and quickly growing
industry in America, namely educational film.

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 FilmStripViewer

As early as 1910, more than 1,000 film titles were catalogued in George
Kleine’sCatalogueofEducationalMotion Pictures.In1923FrankFreemanclassified the existing
educational films into the following four categories: “(1) the dramatic, either fictional or
historical; (2) the anthropological or sociological, differing from the dramatic in that it is not
primarily based on a narrative or story; (3) the industrial or commercial, which show the
processes of modern industry and commerce; and (4) the scientific, which may be classified
into subgroups corresponding to the individual sciences, such as earth science, nature study,
etc.” (Saettler, 1990, p. 97).

Despite the explosion of educational films, conflict emerged between the commercial
interests and the educational interests of the film industry. Concerns about the financial
bottom line led the film industry to develop educational filmswhich some critics claimed
lacked content and were more theatrical in nature. In
addition,teachersoftenwerenotaskedforinputandguidanceinmakingeducational films. As a
result, the films frequently did not meet teachers’ needs. Then, in the late 1920s, sound film
was introduced.

Although the ability to include sound was a step forward for the film industry, it also
contributed to the demise of educational filming. Requiring new and expensive equipment,
production of educational sound films became an expensive endeavor.At a time when
commercial filming was struggling and educators were questioning the merit of film in
classrooms, strong advocacy for educational sound films was lacking.

Although film continued to be widely used by the government for armed forces
training, agricultural demonstrations, and public relations, the impact of film in the classroom
was minimal. As Cuban (l986) described, “film took up a bare fraction of the instructional
day. As a new classroom tool, film may have entered the teacher’s repertoire, but, for any
number of reasons, teachers used it hardly at all” (p. 17). According to Cuban, the main
reasons for the limited instructional use of filmincluded “teachers’lack ofskills
inusingequipmentand film,costoffilms,equipment

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andupkeep,inaccessibilityofequipmentwhenitisneededandfindingandfittingthe right film to the
class” (p. 18).

RADIO

Radio entered the educational system in the early 1920s. Like the early daysof film,
radio was heralded as a tool that would revolutionize classroom teaching. Similar to the
proclamations of Thomas Edison regarding film, William Levenson, the author of Teaching
through Radio, predicted, “The time may come when a portable radio receiver will be as
common in the classroom as is the blackboard. Radio instruction will be integrated into
school life as an accepted educational medium.” (Cuban, 1986, p. 24)

EarlyRadio

In1923 HaarenHighSchoolin NewYorkCitybecamethefirstpublicschoolto use the radio
in classroom teaching. Following a decision by the Radio Division ofthe U.S. Department of
Commerce to license time from commercial stations to broadcast educational lessons, many
more schools and districts bought equipment and made plans to use the radio in classrooms.
Falling equipment prices in the 1930s further increased interest in the instructional use of
radio.

Typically, educational radio programs lasted between 30-60 minutes and were
broadcasted a few times a week. The limited amount of broadcast time “destined radio usage
to be viewed as a supplement to teacher instruction.” (Cuban, 1986, p. 22) Nonetheless, a
wide range of radio lessons were readily available to teachers. “There were broadcasts for
elementary school listeners and for secondary-school students. There were dramatic re-
creations of American history, challenging interpretations of American folk music, delightful
dramatizations of children’s stories
andlegends.Therewere,inshort,avarietyandawealthofcurricularmaterial onthe air.” (Woelfel &
Tyler, 1945, p. 42)

21
 Two survey studies conducted in 1941, one in Ohio and one in Californiafound that
themajority of schools had radio receivers. Moreover, the amount of radio hardware
available to teachers in the 1930s and 1940s exceeded the amount of film hardware available
at the height of film use.

Higher education was also impacted by the invention of the radio. Some colleges and
universities established their own radio stations for instructional use. Ohio State University
first began broadcasting weather reports in 1912. But the radio was not used for instructional
use in higher education until the 1920s, when “schools of the air” were formed. These radio-
based schools partnered with a local radio station, developed curriculum, created lesson
leaflets, produced educational programs, established a weekly schedule forbroadcasts, trained
staff,and ultimately executed the concept of “schools of the air.”

Educational technology zealots initially dreamed of the radio replacing both schools
and teachers. But by the problems with equipment and support as two factors that limited
instructional use of radio. In addition, Saettler (1990) found that schools “fail to use (the radio)
properly or integrate its programming with the school curriculum” (p. 197).

Similar to problems encountered by educational films, another factor that contributed
to the downfall of educational radio was the struggle betweencommercial stations and
educators. A 1925 decision by Herbert Hoover, who was then Secretary of Commerce, to
leave radio in the hands of American business, instead of having it controlled by the
government made efforts to keep educational radio alive exceedingly difficult. Unable to
conduct a unified fight to maintain a presence on radio stations, educational interests in radio
were overpowered by the commercial radio stations united fight against educational radio.
“The networks maintained that allocating frequencies for educational broadcasting would
only disrupt a successful system of broadcasting that had just begun to function well.”
(Saettler, 1990, p. 203) As a result, educational radio languished as the big business of
commercial radio boomed.

By the end of the 1940s, technology proponents had given up on educational radio
and instead began focusing on the use of television in schools, which was perceived to be the
ultimate combination of audio and visual technology.

OVERHEADPROJECTOR

22
 OverheadProjector

In the 1930’s the overhead projector was widely used by the U. S. Military to train
forces during World War II and eventually the device spread to schools.

THETYPEWRITER

An often overlooked form of educational technology, the typewriter is the one form of
mechanical technology that has penetrated and been used by large numbers of students over
several decades. This use, however, has generally been limited to “business” classes that focus
specifically on teaching students how to type. While typewriters were present inmost high
schools intothe 1990s,theyhave been absent from the majority of classrooms and not used
widely throughout a student’s educational experience. However, there are close parallels
between the typewriter and more modem forms of computer-based technologies.

EarlyTypewriter

The first functioning typewriter was marketed and sold by the Remington Arms
Company in 1873. Years of refinement and use in the business world followed this initial
product launch before typewriters were introduced to schools in the 1920’s.
Soonthereafter,BenWoodandFrankFreeman(1932)conductedalarge-scale

23
experimenttodevelopanunderstandingofhowtypewritersmightbeusedinearly elementary
classrooms.

Occurring between 1929 through 1931, Wood and Freeman’s experiment was similar
to many studies of computers conducted during the late 1980s and the 1990s in that the
stated purpose of Wood and Freeman’s investigation was “to study the nature and extent of
the educational influences of the portable typewriter when used as a part of the regular
classroom equipment in the kindergarten and elementary school grades” (p. 1). In other
words, rather than focusing narrowly on how the useof typewriters affected the writing skills
of young children, Wood and Freeman were primarily interested in how instructional
practices and classroom ecology changed. For this reason Wood and Freeman’s study
examined how the typewriter could be integrated into the curriculum and the impacts that it
had on teaching and learning.

Almost 15,000 students from eight public school districts and five private schools
participated in the experiment. Treatment and control groups were formed in order to study
the differences in student learning. Data that was analyzed included achievement test gains,
student writing samples, teacher questionnaires, classroom observations, and student letters
about why they like typewriting.

1930TypingClass

Based upon their study, Wood and Freeman (1932) concluded that there were three
important reasons for using the typewriter in schools:

(1) toteachstudentsskillsthattheywilluselaterinlifeforpersonalor professional
reasons
(2) to enable students to better learn English, spelling, arithmetic,
geography, history, etc.,
(3) todevelopthoseattitudesandhabitswhichconstitutesoimportantapart of the aims
of elementary school education” (p. 179).

Even though Wood and Freeman (1932) found evidence that typewriters could be used
in early elementary classrooms, and this use had a positive impact on
studentlearning,theirrecommendationtoplacetypewritersinallearlyelementary
24
classrooms was never implemented. In part, the high cost required for such large numbers of
typewriters was not feasible, particularly when the nation was struggling with a major
economic depression. Instead of being directly placed and used in classrooms as a writing
tool, typewriters were used to prepare students for the business world by teaching high school
students the professional skill of typewriting.

TELEVISION

Although it wasn’t until the 1950s and 1960s that instructional television reached its
peak, the first documented use of closed circuit television was in Los Angeles public schools
and at the State University of Iowa in 1939. While the popularity of instructional television
was rising between 1939 and the 1950s, the overall United States educational system was
facing harsh criticism.

1950sClassroomTV

Alleged evidence of the ailing educational system culminated with Russia’s launch of
Sputnik in 1957. Fear that the Russians had surpassed the United Statesin science and
technology led to educational reform efforts. Instructional television was viewed as one way
to gain ground in the fight to stay ahead in technology. In response, financial support for
instructional television poured in from many government and industry sources. The Ford
Foundation alone “expended more than
$300 million for the national educational television movement” (Saettler, 1990, p. 372).

Funding was provided for several types of instructional television application similar to
the introduction of film. Some administrators and government officials
hypothesizedthattelevision couldprovidestudents withabettereducation at alower cost. To this
end, a few school systems, such as Hagerstown Maryland and American Samoa, attempted to
substitute a large portion of teacher-led classroom time with educational television
programming. The primary reason for the infusion of television in these communities was the
lack of certified teachers. In most schools,
however,instructionaltelevisionservedasupplementalroleandwasusedminimally. Cuban
estimates that by 1975 primary-grade students spent on average only five hours a week
learning through instructional television (Cuban, 1986. p. 32).

25
 During the 1960s the television industry underwent a major transformation. In 1965, a
Carnegie Corporation Commission recommended that “the federal government establish an
independent, nonprofit Corporation for Public Televisionthat would receive money from the
government and other sources and distribute these funds to individual stations and
independent production centers” (Saettler, 1990, p. 377).

1940’sPhillipsTV

Essentially putting into effect the Carnegie Corporation recommendation the Public
Broadcasting Act was passed in 1967. Two years later, the Corporation for Public
Broadcasting (CPB) was established and in 1970 the Public Broadcasting Service was created
to act as a distribution point and to manage the interconnection between stations.

All of these events in the public television industry would appear to set the stage for
tremendous success of instructional television. However, some critics believe the end result
hurt instructional television more than it helped. For example, Bronson criticized the way
that the CPB handled instructional television, stating thatit “indicates a questionable
bureaucratic concern with directing social change rather than in promoting the development
of educational broad casting” (Saettler. 1990, p. 384).

Although several early studies showed benefits of television over teacher instruction,
later reports revealed that support for instructional television had diminished significantly.
One source of this lack of support was from teachers. Typically, implementations of
instructional television did not considered teacher needs or views. Cuban (1986) describes
how, rather than consulting teachers, “television was hurled at teachers” (p. 36).

26
 ChannelOne

Interest in educational applications of televisions was revived in 1989 when a private,
for-profit company began marketing an educational channel directly to schools. As Saettler
(1990) describes, “Whittle Communications assembled a board of twelve educators and
public figures to provide advice and direction for Channel One, a satellite-received news
programming venture aimed at elementary schools” (p. 533). As an incentive to broadcast
Channel One to students, Whittle Communications offered schools up to $50,000 of free
televisions and video equipmentand1,000hoursofeducationalprogramminginexchange
foraguarantee that students would watch 12 minutes of daily news programs which includes
two minutes of paid commercials each day. Channel One has since changed its focus from
elementary schools to middle and high schools, but maintains the same business plan.

Despite the fact that California and New York banned Channel One, by 1993 more
than 8 million students nationwide watched Channel One’s programming daily (Barry, 1994,
p. 103). Channel One, however, has faced strong opposition. As Saettler (1990) states, “All
critics agree that the classroom should not become another market to exploit” (p. 534).
Channel One is yet another example of the tension, and perhaps incompatibility between
corporate America and the educational system.

TEACHINGMACHINESANDPROGRAMMEDINSTRUCTION

In the 1960s, behavioral psychology contributed to the educational technology field by
introducing “teaching machines.” Reminiscent of Tiu! Turk, an 18th century “computer”
that wore a turban and played chess (Standage, 2002), teaching machines were intended to
teach students through thoughtfully programmed instruction.

27
 TeachingMachine

The premise behind teaching machines was that objectives must be defined in advance
and the extent to which these objectives are achieved must be measured. Students operated
the machines themselves and followed instructions on a screen similar to a television.
Typically, individual student cubicles were set up to block the noise made by the machines.
This format minimized the amount of interactionamong students and between students and
the teacher.

Books accompanied the teaching machines and functioned in an adaptive fashion,so
thatifa studentdidnotunderstand a concept, thestudentis directedtoa sectionthatfurther
explainedit.Ifthe studentexhibitedmasteryof theconcept, heor she was directed to the next
topic. Teachers were able to program the teaching machines based on their desired
curricular goals while students worked at their own pace through the lesson plans. But once
programmed, it was the machine that directed students to the appropriate lesson, either in
books or on the machine.

When using programmed instruction, students were first presented with material in
successively more difficulty steps. The student was then asked to answer a question about the
material. Some questions were multiple choice, while others useda fill in theblank format.The
program thencomparedthe student’s answer with the correct answer. Positive reinforcement
was given to students who responded correctly while the proper response was provided to
students who answered incorrectly. Skinner believedthat allstudentsshouldbe administered
thesame setof questions, and students should be able to answer 95% of the questions correctly.

Later in the life cycle of teaching machines and programmed instruction branching
algorithms and adaptive tests were developed to tailor the material and questions to an
individual student’s needs. In general, evaluation of programmed instruction in the classroom
showed that although implementation was difficult, the combination of teacher instruction
and programmed instruction was more effective than either method used in isolation.

28
 TeachingMachine

Skinner described the key characteristic of teaching machines and programmed
instruction as “the arrangement of materials so that the student could make correct responses
and receive reinforcement when correct responses were made” (Saettler, 1990, p. 294). This
statement points to one of the major sources of conflict in the use of teaching machines. Too
often teachers and administratorsfound themselves caught up in the excitement of using
technology and neglected what many people now recognize as the more important
component- the program of instruction. Students were sometimes bored with the level of
instruction, and other times, they found ways to cheat the system and bypass lessons (p. 303).

Skinner introduced programmed instruction at Harvard University in 1957. A year
later, Evans used the programmed instruction concept in books at theUniversity of
Pennsylvania. The first use of programmed instruction in an elementary school was in 1957
at the Mystic School in Winchester, Massachusetts. In general, though, teaching machines
and programmed instruction were not widely used in public school classrooms or in higher
education.

The popularity of teaching machines and programmed instruction followed the
familiar cycle of most other forms of educational technology. In the late 1950s many people
in the educational technology community expressed praise for this new tool: “In its short
history this area of teaching technology has had a remarkably widespread effect on all forms
of teaching” (Kay, Dodd, & Sime, 1968, p. 1). However, teaching machines and instructional
programming never reached thestage of widespread use and in the late 1960s even the
strongest proponents were backing down from their initial claims. Skinner once said, “…
unfortunately, much of the technology has lost contact with its basic science. Teaching
machines are widely misunderstood.” (Saettler, 1990, p. 303)

COMPUTERS

The research in the 1950s and 1960s on programmed instruction laid the
foundationforthedevelopmentofmoreadvancedlearningsystems.Computers

29
werefirstusedineducationinthe1960sinawaythatwasintendedtoindividualize instruction. This
method became known as computer assisted instruction (CAI).

CAI

CAI was intended to teach students a specific content area. Initially, the only
difference between CAI and teaching machines was the type of technology used to deliver the
material. Drill and practice techniques were common. “The student was asked to make
simple responses, fill in the blanks, choose among a restricted set of alternatives, or supply a
missing word or phrase. If the response was wrong, the machine would assume control, flash
the word ‘wrong’ and generate another problem. If the response was correct, additional
material would be presented.” (Saettler, 1990, p. 307)

The first generation of CAI programs used mainframe computers, was very expensive,
anddid notachieve the expectedbenefitsof improvingeducationthrough computer-based
individualized instruction. However, this initial introduction of computers in schools spawned
interest in a variety of other computer-based applications.

HistoryofComputers

In the late 1970s the cost and availability of microcomputers reacheda level at which it
was more practical to place computers in K-12 schools. For a variety of reasons, parents,
industry leaders, and government officials put pressure on school districts and principals to
introduce computers into the schools. One reason for this
computerenthusiasmwasthefearthattheUnitedStateswascontinuingtofall

30
behind otherworld powers in terms of technology (C. Hunter,1998), and teachingstudents to
learn how to use computers seemed like one solution to this problem.

Another reason for the external pressure to use computers in schools was the
perceivedneedtoteachchildren job-related skills. In thelate1970sandearly1980s, the
importance of computers in the business world increased rapidly. As a result, teaching
students how to use computers provided them with real-world skills and helped them become
more competitive e in the job market.

Finally, it was argued that computers would make the educational process more
efficient. Many computer advocates argued that a more refined version of the mainframe
computer-assisted instruction would allow larger class sizes and, therefore, there would be a
need for fewer teachers, since students would be able to rely on the computer for a significant
portion of their learning.

ClassroomComputer

Depending upon one’s perspective, the use of computers in schools differed
significantly. For example, if the goal was to teach students how to use a computer so that
they could obtain work skills, schools would introduce computer literacy classes into the
curriculum. If the goal was to improve instructional efficiency, the computer was used as a
tool to teach students the predetermined content. Finally, some people argued that the main
benefit of using a computer in the classroom was to improve students’ problem-solving skills.
This debate over how computers should be used in schools still exists today and is strikingly
similar to the differences between Wood and Freeman’s rational for placing typewriters in
elementary classrooms in the late 1920s versus the use of typewriters in business classes to
teach discrete typewriting skills in order to prepare students for the workplace.

But no matter what the intended uses were, computers entered schools in large
numbers during the early 1980s. Cuban (1986) references a survey that found an increase of
100,000 computers in schools over the year and a half between fall 1980 and spring 1982.
Between 1982 and 1984, that number grew to 325,000 computers. By 1988, there were an
estimated 3 million computers in schools (Saettler, 1990, p. 457).

31
 Muchofthisgrowthcanbeattributedtocorporatedonations,whichcompanies made in an
effort to gain an edge in the educational computing market. Throughout the 1980s, IBM,
Apple Computer, Hewlett-Packard, and Tandy all donated substantial numbers of computers
to public schools. In elementary schools, these computers were generally used for repetitive
drilling of specific content. In high schools, computers were generally used to teach students
computer skills.

EarlyEducationSoftware

By the end of the 1980s, computers came under heavy scrutiny. Government leaders,
parents, and school administrators wanted evidence of the effectiveness of using computers in
schools. Instead of detailing benefits, researchers revealed a list ofobstacles to
theuseofcomputers inclassrooms. Similar totheproblemsidentified with film, teachers felt that
they were generally excluded from the development of instructional software and that the
commercially available software generally did not meet their needs. Specifically, teachers felt
that many of the available software packages did not engage students,andteachers felt that
thedrill andpracticeformat was not an effective use of students’ time. Again similar to film,
teachers also did not have the time or expertise to develop their own computer-based
instructional materials. Finally, technical problems further frustrated teachers. All of these
problems contributed to low usage. Saettler estimates that, on average, in the late 1980s, a
typical student used a computer for less than 30 minutes a week.

In contrast to the 1980s, the 1990s was a decade of new ideas andinnovations for
computer use in classrooms. With the introduction of color monitors and graphical user
interfaces, more interactive and interesting content-based software packages were developed
by companies like Tom Snyder Productions. In addition, simulations, intelligent tutors and
cognitive-based learning tools such as DIAGNOSER (Minstrell, Stimpson, & Hunt, 1992) or
the Algebra Cognitive Tutor (Anderson et al., 1995) began to show promise for improving
classroom learning. Schools also began to understand the benefit of helping teachers
determine how to integrate computers into their curriculum. While these advances did not
correct allthe obstacles to computer use identified by teachers during the late 1980s, they
reignited interest in instructional uses of computers.

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 LEARNINGMANAGEMENTSYSTEMS

Whiteboard

Learning Management Systems (LMS), also known as Instructional Management
Systems are online collaboration and communication tools which enable administrators,
teachers and students to collaborate and communicate online in real-time across geographic
distance. Some of the more popular commercial and opensourceLMSinclude
BlackboardLearningSystem, Share-Point LMS, ANGEL Learning Management Suite,
Sakai, and Moodle.

LMS combine online course management, communication and collaboration tools
which can include a discussion forums, file exchange, email, online journal/blog, real-time
chat,interactive
whiteboards, bookmarks, calendar, search tool, group work, electronic portfolio,
registration integration,hosted
services, quizzes/surveys,marking tools/grade book,student tracking,content sharing and
objectrepositories, amongst othertool offerings. (Fox,C., et al. (2009) pg. 8).

INTELLIGENTTUTORING

Neuroplasticity

The field of cognitive science has exploded over the past decade and computer
applications have emerged to take advantage of this new knowledge of
howthebrainworks.Mergingthefieldsofeducationandcognitivesciencehas

33
proven to be difficult. Bruer (1998) describes, “New results in neuroscience, rarely mentioned
in education literature, point to the brain’s lifelong capacity to reshape itself in response to
experience.The challenge for educators is to develop learning environments and practices
that can exploit the brain’s lifelong plasticity,” (p. 9). One practical application of lessons
learned from programmed instruction and new information about how the brain works came
in the 1990’s in the form of intelligent tutoring.

For the past decade, Carnegie Mellon has been developing cognitive tools. Carnegie
Mellon’s first major tool, called the Practical Algebra Tutor (PAT), strives to improve
students’ algebra skills and contains “a psychological model of the cognitive processes behind
successful and near-successful student performance” (Koedinger, Anderson, Hadley & Mark,
1997, p. 32).

IntelligentTutoring

PAT is computer-based, uses real-world problems, and allows students to use several
tools to solve a given problem. One example of a PAT problem is to determine which car
rental company should be used on a vacation, given differing cost and terms of agreement
information. Feedback is given to the student while he or she is solving the problem, allowing
student misconceptions to be addressedwhilethestudentisstill engagedwith
theproblem.PATusesmodeltracingtotracka student’s progress throughout a problem and
knowledge tracing to track a student’s progress in a series of problems. A Bayesian model,
which estimates whether a student possesses a certain skill or knowledge of a particular
subject, is used to highlight each student’s strengths and weaknesses. This information is then
used to choose the next problem to be administered and to pace students.

ThePATprogramwasfirst pilottestedin1993inthreePittsburghhighschools. Since then,
the intelligent tutoring tools have been expanded to include a fully developed series of
products (Algebra I, Geometry, Algebra II, Integrated MathSeries and Quantitative Literacy)
that are being used throughout the country.Through a series of studies conducted over the
past decade (see Corbet, 2002 for a review of this research), evidence suggests that a diverse
population of students “includingmainstream,non-
mainstream,gifted,minority,ESLandinclusive

34
educationstudentsallbenefit”fromtheuseoftheCognitiveTutor®curricula (Carnegie Learning,
2002, para.

IntelligentTutoring

Similarly, researchers at the Concord Consortium have been working on an
intelligenttutoringdevice thatfocusesongeneticsand scientificreasoningskills. The system is
intended to help eighth-, ninth-, and tenth-grade students learn about genetics through
guided exploration. Most often, the system introduces students to new concepts by asking
students to explore a specific topic through manipulation of genetic traits of a fictitious species
of dragon.As students work with the system,new concepts are revealed through guided
exploration. For example, the first set of explorations during one lesson culminates by asking
students to describe how traits are produced in dragons.

At times, the learning system presents textual or graphical information to explain
concepts and provides students with access to various tools and pieces of information via
menu selections. In addition, the system often asks students to demonstrate their
understanding through written responses to specific questions, multiple-choice questions and,
most often, the modification of different aspects of genetic codes to create dragons with
specific traits or to determine how a trait suddenly appears in a generation of dragons. From
an instructional perspective, Biologica enables students to explore a complex topic via a
variety of media and enables teachers to work individually or with small groups of students as
questions arise.

Althoughthesetoolsarebeingusedinarelatively smallnumberofclassrooms, they show
tremendous promise for using technology as a tool that assists students and teachers in both
identifying and correcting misconceptions in a timely manner.

THEINTERNET

35
 VirtualLearning

Today, the Internet is one of the more popular forms of educational technology used
in classrooms. Although some college level courses can be taken online, often
withoutanystudent-teacher interaction,thistype ofuseis justbeginningtopenetrate K-12 public
schools, particularly at the high school level.As an example, the Virtual High School (VHS)
was launched in the late 1990s. Since then, VHS has grown and served approximately 3,000
students in more than 150 schools with 134 online courses in 2001. Similarly, the Florida
Virtual School provides free, online instruction to 6,900 students enrolled in 65 Florida
county school systems.
In addition to online courses, there are a variety of ways that the Internet is being used
in classrooms. A 2002 study by the American Institutes for Research found that students use
the Internet for school in the following five ways:

asavirtualtextbookandreferencelibrary
1. asavirtualtutorandstudyshortcut
2. asavirtualstudygroup
3. asavirtualguidancecounselor
4. asavirtuallocker/backpackandnotebook

Scatterspots

(Levin & Arafeh, 2002, p. iii). Teachers also integrate Internet-based activities into
their lessons. In some cases, teachers will use data or simulations available on the Internet to
demonstrate a concept or work through a problem with the whole class. With the rapid
increase in Applets (mini-applications that are available on the
Internet),teachershaveaccesstopowerfultoolsthatenableeasymanipulationof

36
 dataanddisplays informationinamannerthatoftenmakesiteasierforstudentsto visualize concepts.

As one example, the Technology and Assessment Study Collaborative has developed a
set of applets that focus on specific statistical concepts
(www.bc.edu/research/intasc/tools.shtrnl).These tools enable teachers and students to
generatescatterplots thatmeet specificconditions(e.g.,a correlation betweentwo variables of.65
with 200 cases). The correlation applet also allows the user to move individualdatapoints
aroundwithin thescatterplotandthenseehowthischange ina single data point affects the
correlation. In addition, the applet allows the user to manipulate a “line of best fit” by
clicking and dragging it on the screen. As the line is moved, the error of prediction is updated
automatically enabling the user to visually explore how changes in the line affect the accuracy
of the prediction. Applets developed by other organizations allow teachers to model scientific
principles such as plate tectonics and sound waves by manipulating data and then
visuallydisplaying the effects.

Internet

Teachers also direct students to use the Internet to find and explore information
related to a specific topic of study. As an example, many upper elementary and middle school
teachers have students perform web-quests. In some cases, web-quests take the form of
problems that require students to find and apply information to solve. As an example, a
teacher might present a problem in which an animal that lives in Australia has decided to
relocate to one of three areas within the United States.Students are then asked to use the
Internet to find specificinformation about the animal and about each area of the United
States and to then use this information to write a recommendation to the animal that includes
data to supportthe recommendation. Inothercases,web-quests takeamore mundane form in
which students are given a list of actual questions and are asked to use the Internet to find the
answers.

Whiletherearemanymoreexamplesofcomputer-basedtoolsthatareusedintoday’s classrooms, there
is no question that computers are the most recent technologythat
haspenetratedtheAmericaneducationalsystem.However,an

37
importantquestionthatremainslargelyunansweredfocusesonhowcomputerusein schools is
affecting teaching and learning.

THECLOUD

Although technically part of the internet, because of its impact on K-12 education
cloud technology should be looked at separately.

Cloud computing relies on sharing of resources to achieve coherence and economies of
scale, similar to a utility (like the electricity grid) over a network. At the foundation of cloud
computing is the broader concept of converged infrastructureand shared services. Cloud
resources are usually not only shared by multiple users but are also dynamically reallocated
per demand. This approach maximizes the use of computing power thus reducing
environmental damage as well since less power, air conditioning, rack space, etc. are required
for a variety of functions. With cloud computing, multiple users can access a single server to
retrieve and update their data without purchasing licenses for different applications.

CloudTechnology

The present availability of high-capacity networks, low-cost computers and storage
devices as well as the widespread adoption of hardware virtualization, service-oriented
architecture and autonomic and utility computing have led to a growth in cloud computing.
School districts can scale up as computing needs increase and then scale down again as
demands decrease. (Wikipedia)

Different schools use different devices at different grade levels which mean varying
data storage needs. And, for example, there is no need to shoehorn an infrastructure built for
the Android operating system to fit a Mac-only school. Using “standards-based vendor
control” cloud technology allows the accommodation of the districts for any device choice,
whether it is a Chromebook, an Android device, or an Apple device which typically have no
hard drives. The cloud technology allows the schools to pick the device and to find the
common denominators in deliveringsupport services.

38
 Freedom of choice applies to where students can do their work. A lot of local school
districts rely on local outreach programs from their city, from local businesses where students
might have remote labs. They might have libraries or boys and girls clubs where they need
access to their information on a device that they might beable to have for an hour or two at a
time. Cloud technology allows the entire curriculum and supplements to be connected to the
student’s online identity and account—and not to a specific device.

Cloud technology allows secure access for students, teachers, and administrators to
enter cloud storage from any device at any time, via a Dropbox- style entrypoint. And the
cloud islarge enough to accommodate an “archive forever” infrastructure. This means that
teachers retain access to curriculum and studentdata, while students can always access
projects that might be part of an e-portfolio.

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40