History in Pictures
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Overview
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These historic photos depict elements
of Doug Engelbart's work beginning in the early 1960s at
Stanford Research Institute (now SRI International). For more background, see the brief
biography "A Lifetime Pursuit," as well as Engelbart's 1986 lecture The Augmented Knowledge Workshop and its companion paper "Workstation History and The Augmented Knowledge Workshop" for a guided tour of these and other photos in their historical context.
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Additional photo collections can be found on Facebook in the Doug Engelbart Institute Albums and the ARC Bootstrapper Albums, in the MouseSite Photo Gallery at Stanford University, in several of the Online Exhibits at the Computer History Museum, SRI's Engelbart Storykit page, and amongst Engelbart's published papers.
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Mouse and workstation
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For more on this topic, including story, links to archive footage, etc., see our portal page on The Mouse. For deeper background on early display technology, see "Workstation History and The Augmented Knowledge Workshop" (Engelbart, 1986); and for details on early experiments with pointing devices, see "Display-Selection Techniques for Text Manipulation" (Engelbart et.al. 1967).
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Display selection experiments. In search of a best way to select screen objects for
interactive display workstations; Engelbart
launched experiments managed by Bill English, beginning in late 1963 or early 1964. They selected a variety of
available pointing devices -- light pen, track ball, joystick, and
Grafacon (pictured here), and also invented one that would roll around on the table top called a 'mouse'. The devices were compared for
speed and accuracy, with the mouse coming out on top. Still other
prototypes were later built and tested, including
foot-pedal operated, knee-operated, even head-operated ("nose pointing").
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First mouse. - Doug Engelbart
invented the computer mouse in 1963, built by his lead engineer Bill English as part of an experiment to find better
ways to point-and-click on a display screen. Made in a shop at SRI, the
casing was carved out of wood. It had only one button, which was all
there was room for. Subsequent models featured three buttons.
Engelbart would have gone for even more buttons, but there was only room
for three of the needed micro-switches available in those days.
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First mouse perspectives. - Two wheels,
perpendicularly mounted to one another in the mouse's innards track the
X-Y position that is communicated to the screen. The mouse was patented
in 1970 as an "X-Y Position Indicator." Xerox Park is often credited,
erroneously so, with the invention of the mouse, but they do have to
their credit the trackball that has replaced the perpendicular wheels.
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Workstation with mouse.- The mouse was
invented for use with display workstations that were pioneered in
Engelbart's laboratory, the Augmentation Research Center. This model, of circa
1964-1966, was custom-built for roughly $80,000. A second device with
buttons, on the left, is the forerunner of the keyset
designed for the rapid input of command codes for manipulation of blocks
of text. The keyset is, for that purpose, more efficient than the common
keyboard.
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First production keyset. -
Engelbart invented a document generation and editing system with which a
number of people can work together. It was known as the NLS (oN-Line
System). It called for streamlining the commands for operating the
computer and manipulating documents. Engelbart looked for
single-character inputs, such as a d for delete. He then
came up with the keyset for chording the command keys with the left hand
while the mouse was worked with the right hand.
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A cue card for the keyset, or "chord".
- The keyset's five keys permit 31 combination of pressed
keys. That covers more than the alphabet. Letters, beginning with a,
are shown on this cue-card chart. Uppercase characters are obtained by
simultaneously pressing the middle mouse button. With the left mouse
button pressed, the keyset is used for entering digits and punctuation
marks. Tests done in the early '60s showed that temporarily secretarial
helpers (known as the "Kelly Girls") mastered the keyset in less than
two hours no-matter what method of training was used. They also
demonstrated that the regular keyboard is more efficient for
straightforward typing, but that for editing and maneuvering text, the
mouse-keyset combination is the more efficient.
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Production mouse. - This model was
used by the Augmentation Research Center group and the customers served
over the ARPAnet. It is also the mouse used in the 1968 FJCC demo.
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Production workstation and mouse. -
The first production model of the mouse was made in 1967. It had a
plastic casing on a metal base plate. Although the casing was originally
designed for the cord to be attached to the wrist side of the device, it
is seen here with the cord coming out from the other end.
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Ergonomic keyboard console. - This
console was custom-made by Herman Miller furniture company of Zeeland,
Michigan, and used during the 1968 Fall Joint Computer Conference at
which Doug Engelbart gave his historical demonstration of on-line
computing. The setup included a tilt-swivel office chair.
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Doug Engelbart and mice. - Engelbart,
in his office at Tymshare, shows the original mouse next to the then
latest, 1984 model. Upon acquiring the NLS co-operative text-editing
system from SRI, Tymshare renamed the system Augment.
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ARC lab environment
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For background on the experimental environment in the Augmentation Resources Center lab see "Workstation History and The Augmented Knowledge Workshop" (Engelbart, 1986).
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Experimental workplace and
closeup of a knowledge
worker. - Engelbart's Augmentation Research Center (ARC) at SRI
experimented with various office and seating arrangements, and with
several keyboard-display configurations, even beyond the bounds of
existing conventions.
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Engelbart in his ARC office. - Doug
Engelbart at his first personal display workstation, - This station was
installed in his own office in 1974. Until then, all the ARC's display
workstations were situated in an
open arena
shared by all his engineers.
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Pictures
(top and
bottom)
show Doug and staff using NLS to support 1967 meeting with sponsors -- probably the first computer-supported conference.
The facility was rigged for a meeting with representatives of the ARC's
research sponsors NASA, Air Force, and ARPA. A U-shaped table
accommodated setup CRT displays positioned at the right height and angle.
Each participant had a mouse for pointing. Engelbart could display his
hypermedia agenda and briefing materials, as well as the documents in
his laboratory's knowledge base. See also Father of Groupware and Working Together. 3c
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NIC archives (1971). - The host
mainframe at ARC was the second such unit linked into the ARPANet, which
was the precursor of the Internet. Engelbart's lab had been assigned by
ARPA to run the Network Information Center (NIC), which has since grown
into the InterNIC. This photo shows
the NIC archives vault with its library of NIC publications and backup
tapes (magnetic 7- or 9-track tapes).
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Tree of evolution. - Chart shows
progression of ideas from Engelbart's Augmentation Research Lab at SRI
(SRI-ARC) migrating to Xerox, the Apple Computer Co., and beyond. (Slide
by Charles Irby who migrated from Engelbart's lab to Xerox PARC,
Metaphor, and is now at SGI.)
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FJCC 1968 "Mother of All Demos"
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See our 1968 Demo page for a bit of background and links to the demo and other related resources.
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First ever video teleconference.
- A screen shot of simultaneous on-screen video
teleconferencing and shared screen shows ARC's Bill Paxton piped in from the SRI lab in
Menlo Park as he demonstrates NLS's information retrieval capability.
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Forty miles from the conference site. -
Display-driver equipment room at Engelbart's SRI laboratory in Menlo
Park during a rehearsal for 1968 FJCC demonstration. From left to right,
unknown woman, Martin Hardy, Dave Casseres, Ed van de Reit, unknown man,
Stewart Brand, Roger Bates, Bill English.
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Using early display technology. - At the ARC lab in Menlo Park, a
commercial camera was used to capture and pipe the computer's display imagery to the desired workstation real-time. Up to twelve workstations could be served thusly simultaneously from a bank of such cameras. For the demo, the live capture piped to Doug's workstation was transmitted via phone lines to San Francisco's Civic Auditorium 40 miles away, onto Doug's monitor where he sat on stage and also projected on a huge screen for the audience benefit. An engineer is seen adjusting the camera's focus.
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NLS/Augment architecture
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Images to illustrate concepts
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Tricycle vs
bicycle. -
Engelbart used these images to illustrate the difference between ease of
use and high-performance. The tricycle may be easier to learn and use,
but it is hard work to travel even a short distance. Riding a bicycle
calls for considerably more skill, with bumps and bruises expected as
one learns, but the effort-to-performance ratio is dramatically higher.
The high-performance knowledge workers of the future, as perceived by
Engelbart, are expected to be very skillful.
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Skiing on birch slats vs
downhill skiing
provides a similar analogy for comparing a high-performance worker
flying through information space as compared to plodding with a
one-button mouse and menus without the prospect of ever graduating to
anything faster.
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Potter's wheel. - An example of how
any trade or profession has evolved tools and methods in which the
tradespeople become extremely proficient in their use. The knowledge
work profession is relatively young and less evolved, and professionals
are not expected to become proficient soon except in the most
rudimentary skills.
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Helicopter pilot. - For those who are
not highly trained or certified, the services of a pilot are the answer.
Passengers are not expected to fly a helicopter; the pilot does that.
Similarly, we should expect executives and average knowledge workers
wishing to fly through complex or unfamiliar information space to employ cyber pilots.
Those can take them were they need to go, help find what is needed, give
guided tours, etc. This assistance could quite easily be done
remotely, for example, by video teleconferencing as shown above.
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Hangglider. - Engelbart often concluded his presentations with this inspirational
parable of soaring elegantly up above the horizon.
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Behind the scenes at ARC
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Working on the hardware (top), and 1969-era teletype with ARPANET "Interface Message Processor" or "IMP"
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Presidential Award
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See our National Medal of Technology page for a description of Doug's award and ceremonies.
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President Clinton and Douglas Engelbart
Courtesy The White House.
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President Clinton, Secretary Mineta, and NMT Laureates
Courtesy The White House.
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Secretary of Commerce Norman Mineta and Douglas Engelbart
Courtesy National Science Technology Medal Foundation.
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More Photos
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