Interaction design has evolved over centuries as tools were developed to fit the human form and capabilities. Early tools like knives and plows were designed based on the human hand and strength. Later, the Industrial Revolution led to an emphasis on productivity over fit, exemplified by Taylor's scientific management techniques. World War II spurred advances in aviation psychology and computing to better match technologies to humans. Pioneers like Turing and von Neumann helped develop the modern computer architecture still in use today by envisioning machines as universal problem solvers rather than dedicated calculators. The evolution of interaction design has increasingly focused on adapting machines to people rather than people to machines.
8. An undetected error in a logarithmic table is
like a sunken rock at sea yet undiscovered,
upon which it is impossible to say what
wrecks may have taken place.
—Sir John Herschel (1842)
First published table of Logarithms by John Napier, 1614
http://www.math.yorku.ca/SCS/Gallery/images/dan/napier_logtable.jpg 8
10. CHARLES BABBAGE
“
(1791–1871)
As soon as an Analytical Engine
exists, it will necessarily guide the
future course of the science.
Whenever any result is sought by
its aid, the question will then arise
— by what course of calculation
can these results be arrived at by
the machine in the shortest time?
—Passages from the Life of a
Philosopher, ch. 8 “Of the
Analytical Engine”
http://en.wikipedia.org/wiki/File:CharlesBabbage.jpg 10
15. “
ADA LOVELACE
(1815–1852)
The Analytical Engine weaves algebraic patterns,
just as the Jacquard loom weaves flowers and
leaves.
Many persons who are not conversant with
mathematical studies imagine that because the
business of [the Engine] is to give its results in
numerical notation, the nature of its processes
must consequently be arithmetical and numerical,
rather than algebraical and analytical. This is an
error. The engine can arrange and combine its
numerical quantities exactly as if they were
letters or any other general symbols; and in fact
it might bring out its results in algebraical
notation, were provisions made accordingly.
http://upload.wikimedia.org/wikipedia/commons/8/87/Ada_Lovelace.jpg 15
16. (1880)
THE CENSUS
16
http://upload.wikimedia.org/wikipedia/en/b/b0/1880_census_Hollerith.gif
17. HERMAN HOLLERITH
(1860 – 1929)
http://www.census.gov/history/img/Hollerith.jpg http://www.columbia.edu/acis/history/1890-card.gif 17
22. THOMAS J. WATSON
“
(1874 – 1956)
Good design is good business.
Design must reflect the practical and
aesthetic in business but above all...
good design must primarily serve
people.
22
24. “ One place where IBM did succeed was in keeping
viable the basic input medium of the punched
card, and with that the basic flow of data through
a customer’s installation. The same card, encoded
the same way and using a keypunch little changed
since the 1930s, served IBMs computers through
the 1960s and beyond. The sequential processing
and file structure, implicit in punched card
operations, also survived in the form of batch
processing common to most mainframe computer
centers of the 1960s.
—Ceruzzi, A History of Modern Computing
24
26. F.W. TAYLOR
“
(1856 – 1915)
Now one of the very first requirements
for a man who is fit to handle pig iron as a
regular occupation is that he shall be so
stupid and so phlegmatic that he more
nearly resembles in his mental make-up
the ox than any other type. The man who
is mentally alert and intelligent is for this
very reason entirely unsuited to what
would, for him, be the grinding monotony
of work of this character.
http://explorepahistory.com/images/ExplorePAHistory-a0j8p9-a_349.jpg
26
29. “ Because this was total war, involving great masses
of men and women, it was no longer possible to
adopt the Tayloristic principle of selecting a few
specialized individuals to match a pre-existing job.
The physical characteristics of the equipment now
had to be designed to take advantage of human
capabilities and avoid the negative effects of
human limitations.
Obviously such a sea change in philosophy did not
occur over night.
—David Meister, The History of Human Factors and Ergonomics
29
33. “
VANNEVAR BUSH
(1890 – 1974)
Vannevar Bush is a great name for
playing six degrees of separation.
Turn back the clock on any aspect of
information technology — from the
birth of Silicon Valley and the
marriage of science and the military to
the advent of the World Wide Web —
and you find his footprints. As
historian Michael Sherry says, "To
understand the world of Bill Gates
and Bill Clinton, start with
understanding Vannevar Bush.
—G. Pascal Zachary, The Godfather
33
40. “
ALAN TURING
(1912 – 1954)
I believe that at the end of the
century the use of words and
general educated opinion will
have altered so much that one
will be able to speak of
machines thinking without
expecting to be contradicted.
—Mind, vol. 59, #236 (1950)
http://www.alanturing.net/turing_archive/graphics/photos%20of%20Turing/photoindex.htm 40
41. “ Numerical integration is where you take the path of a bullet
from the time it leaves the muzzle of the gun until it reaches
the ground. It is a very complex equation; it has about
fifteen multiplications and a square root and I don’t know
what else. You have to find out where the bullet is every
10th of a second from the time it leaves the muzzle of the
gun, and you have to take into account all the things that
are going to affect the path of the bullet.
—Kathleen McNulty
41
44. “ The principle flaw was ENIAC’s inability to hold
easily altered instructions in its memory. Every
time the machine needed reprogramming,
operators had to run around the room turning
dials, throwing switches, replugging cables, and
rolling function tables about.
It was realized that this whole method of
programming was a clumsy method, and
archaic… but it did not matter with firing tables,
which permitted the same program to run for
weeks.
—Joel Shurkin, Engines of the Mind
44
46. JOHN VON NEUMANN
“
(1903 – 1957)
It would appear that we have
reached the limits of what it is
possible to achieve with
computer technology, although
one should be careful with such
statements, as they tend to
sound pretty silly in 5 years.
http://en.wikipedia.org/wiki/File:JohnvonNeumann-LosAlamos.gif
46
47. NEXT WEEK
Computing Technology in the Workplace
_The First Business Computers
_Man-Computer Symbiosis
_The Cognitive and the Physical
_The Command Line
PAPERS DUE
Editor's Notes
Mathematician and economist
Used principles of mass production technology
Adam Smith’s pin making factory
Where individual workers are slower than specialized workers
Would eventually be replaced by pin making machine
All it could really do is add! (Or count.)
Machine would be able to be programmed with cards and perform conditional operations
Much more similar to the design of a modern computer with:
• Store (Memory, where variables can be retained and acted upon later)
• Mill (CPU, where variables are brought to be processed)
Two sets of punched cards:
• Operation cards for programming
• Variable cards for data
Mandated by the constitution, we have never missed a census
Previous technological innovation was a box with a roll of paper, helped keep columns neat
Growth in people in the US matched by growth in # of questions asked
Concern that it would so long to compile the census that it wouldn’t be finished before the next one started
Hollerith saw a “punch photograph” on a train -- punched ticket with holes for male, hair color, height, etc
Tested out his machine with NY health department
Complex system required holes to mean multiple things when punched in combination (like shift key)
Success led to a contract with the census
One variable required punching a billion holes. Each day they dealt with a stack of paper taller than the washington monument.
The results of a tabulation are displayed on the clock-like dials. A sorter is on the right. On the tabletop below the dials are a Pantographic card punch (explained below) on left and the card reading station ("press") on the right, in which metal pins pass through the holes, making contact with little wells of mercury, completing an electrical circuit. All of these devices are fed manually, one card at a time, but the tabulator and sorter are electrically coupled.
Each completed circuit caused an electromagnet to advance a counting dial by one number. The tabulator's 40 dials allowed the answers to several questions to be counted simultaneously. At the end of the day, the total on each dial was recorded by hand and the dial set back to zero.
1. The circuit-closing press ("card reader")
2. diagram of press
3. hand insertion of card into a sorter compartment that opened automatically based on the values punched into the card
4. tallying the day's results.
The work was not fun for the young women who operated the machines, many of whom were driven to near madness by the monotony of the work. Mechanics came in frequently to fix the machines. The problem was that someone had extracted the mercury with an eyedropper and squirted it out, so she could get a little rest.
Hollerith grew upset that his workers were relaxing in the bathroom. Rigged a set of filed-down nails in the toilet seat and ran wires from them to an engine in his office. He would spy on workers through a peep hole and if he thought they spent too long sitting on the toilet, he would turn a crank and send a jolt of electricity to rouse them from their throne.
Eventually Hollerith’s Tabulating Machine company went on to work for railroads, had a patent battle over the 1910 census, and sold the company.
In 1911, financier Charles R. Flint directed the merger of the International Time Recording Company, the Computing Scale Company and the Tabulating Machine Company to form the Computing-Tabulating-Recording Company (CTR).
In 1914 Thomas J. Watson, Sr., was named general manager of CTR. Watson emphasized research and engineering, and introduced into the company his famous motto “THINK.”
In 1924, the Computing-Tabulating-Recording Company adopted the name International Business Machines Corporation.
Top salesman at NCR (National Cash Register)
Unethical business practices where he would buy up second hand machines and sell them cheaply, to put other secondhand sellers out of business
Took the fall for this and was fired
Became President of CTR, later changed to IBM
IBM was immune to recessions because of the “rent and refill” nature of the business
Machines were rented and customers had to purchase special cards from IBM
Like razors and blades, or cameras and film
Even if they didn’t get any new customers they still made money
Cards themselves were 10% of sales but 30-40% of profits
Early punch card inputs based on the size of the card, IBM went from 45 to 80 columns in the 30s, Remington Rand came out with a 90 col card. Limits to sizes of cards based on physical properties, too many punches and the card would become unstable. This impacted computers up until the GUI, the size of the terminal window was based on the size of the IBM punch card.
In a typical punch card installation, the same operation was performed on all the records in a files as a deck of cards went through a tabulator or other machine. The UNIVAC and its successors could operate that way but they could also perform a long sequence of operations on a single datum before fetching the next record from memory. In punched card terms, that would require carrying a deck of a singe card around the room, Hardly an economical use of the machinery or the people. Processing information gathered into a deck of cards was entrenched into business practices by the mid-1930s and reinforced by the deep penetration of the punched card equipment salesmen into the accounting offices of their customers.
Loren Wilton (of Burroughs/Unisys, who worked with early IBM gear while in college) recalls (31 Dec 2003):
The Backspace key was only useful in the rare case that you spaced past a column that you needed to punch; you could backspace and restrike the column. Of course if the column was mispunched, you swore under your breath, hit the release key to feed the current card, duped up to the error using the next blank card, then continued punching from that point. When you released this card (or it auto-released after column 80) you quickly grabbed the mis-punched card out of the flipper as it was being stacked and threw it in the trashcan, which was invariably on the left side of the keypunch for this purpose.
Taylor's methods began from his observation that, in general, workers forced to perform repetitive tasks work at the slowest rate that goes unpunished.
Taylorism is a variation on the theme of efficiency; it is a late-19th-and-early-20th-century instance of the larger recurring theme in human life of increasing efficiency, decreasing waste, and using empirical methods (time and motion studies) to decide what matters.
Taylorism can be seen as the division of labour pushed to its logical extreme, with a consequent de-skilling of the worker and dehumanisation of the workplace.
• Shift in decision making from employees to managers -- division of labor
• Develop a standard method for performing each job -- decisions based upon tradition and rules of thumb should be replaced by precise procedures developed after careful study of an individual at work
• Select workers with appropriate abilities for each job -- fit the man to the job
• Train workers in the standard method previously developed
• Support workers by planning their work and eliminating interruptions -- give rest breaks
• Provide wage incentives to workers for increased output
Six Sigma or Lean Manufacturing compared with “Design Thinking”
What changed that was the war
In 1943 Lt. Alphonse Chapanis was called on to figure out why pilots and copilots of P-47s, B-17s, and B-25s frequently retracted the wheels instead of the flaps after landing. Chapanis, who was the only psychologist at Wright Field until the end of the war, was not familiar with the ongoing studies of human factors in equipment design. Still, he immediately noticed that the side-by-side wheel and flap controls-in most cases identical toggle switches or nearly identical levers-could easily be confused. He also noted that the corresponding controls on the C-47 were not adjacent and their methods of actuation were quite different; hence C-47 copilots never pulled up the wheels after landing.Chapanis realized that the so-called pilot errors were really cockpit design errors and that by coding the shapes and modes-of-operation of controls the problem could be solved. As an immediate wartime fix, a small, rubber-tired wheel was attached to the end of the wheel control and a small wedge-shaped end to the flap control on several types of airplanes, and the pilots and copilots of the modified planes stopped retracting their wheels after landing. When the war was over, these mnemonically shape-coded wheel and flap controls were standardized worldwide, as were the tactually discriminable heads of the power control levers found in conventional airplanes today.
Human factors concerns emerged during World War II as a result of the work and experience of a number of specialists involved in the study of then-current manned systems. These systems included those operating on the earth’s surface, under the sea, and in space. Human factors studies were made of:
systems performance
problems encountered in information presentation, detection, and recognition
related action controls
workspace arrangement, and
skills required
Research in these areas ensued, with particular emphasis on human operations. This offered the opportunity for early improvements in performance and safety, as significant modifications of equipment were unlikely under wartime circumstances. Attention was focused on operations analysis, operator selection, training, and the environment associated with signal detection and recognition, communication, and vehicle control. Concurrently, human factors work in industry was focused on efficiency, task analysis, and time-and-motion studies. With the coming of peace, human factors activity was broadened to include systems design more completely. As a result, human factors requirements were incorporated into government phased-procurement contracts with industry. This led to the utilization of human factors specialists by industry and gradually resulted in their involvement in nonmilitary systems and equipment.
What was the first computer used during WWII
During World War I, Bush had known the lack of cooperation between civilian scientists and the military. Concerned about the lack of coordination in scientific research in the U.S. and the need for mobilization for defense, Bush in 1939 proposed a general directive agency in the Federal Government. When the Germans invaded France, Bush decided speed was important and contacted President Roosevelt directly. He managed to get a meeting with the President on 12 June 1940 and took a single sheet of paper describing the proposed agency. Roosevelt approved it in ten minutes.
During 1941 the NDRC was subsumed into the Office of Scientific Research and Development (OSRD) with Bush as director, which controlled the Manhattan Project until 1943 (when administration was assumed by the Army) and which also coordinated scientific research during World War II.
ORSD eventually by 1950 became the National Science Foundation (NSF), which funds university professors, and the Advanced Research Project Agency (ARPA), the Pentagon's chief avenue for basic research, which may be familiar to you from the ARPANET, the precursor to the internet.
What’s the difference?
An analog computer (spelled analogue in British English) is a form of computer that uses the continuously-changeable aspects of physical phenomena such as electrical,[1] mechanical, or hydraulic quantities to model the problem being solved. In contrast, digital computers represent varying quantities incrementally, as their numerical values change.
Bill Tutte, a cryptanalyst at Bletchley Park, discovered that the keystream produced by the machine exhibited statistical biases deviating from random, and that these biases could be used to break the cipher and read messages.
Colossus was the first combining digital, (partially) programmable, and electronic. The first fully programmable digital electronic computer was the ENIAC which was completed in 1946.
By V-E day a total of 10 Collossi were in use at Bletchley Park
Electronic Numerical Integrator and Calculator
Built for ballistics research to calculate trajectories of projectiles
Calculating 1 trajectory took 20 hours using slide rules
Needed to calculate hundreds of trajectories, which took thousands of hours
Electronic Numerical Integrator (or ENIAC) could calculate a trajectory in 1 second
Could be reconfigured to perform limitless steps and iterative loops of operations
But NOT a stored program device
18,000 vacuum tubes
Used standard IBM punch cards for input and output
Cables, plugged into large plugboards, handled programming (sequence of operations)
Took two days to make all the necessary connections to set up a new problem
Once set up, might solve that problem in minutes
By rewiring the computer, people transformed it into a different special purpose computer each time
More modern computers could do that automatically
Here a person had to do it
ENIAC was a transitional device that had high processing speed and was flexible
But had many of the limitations of calculators, tedious setup, decimal rather than binary
The earliest computing machines had fixed programs. Some very simple computers still use this design, either for simplicity or training purposes. For example, a desk calculator (in principle) is a fixed program computer. It can do basic mathematics, but it cannot be used as a word processor or a gaming console. Changing the program of a fixed-program machine requires re-wiring, re-structuring, or re-designing the machine. The earliest computers were not so much "programmed" as they were "designed". "Reprogramming", when it was possible at all, was a laborious process, starting with flowcharts and paper notes, followed by detailed engineering designs, and then the often-arduous process of physically re-wiring and re-building the machine.
A stored-program digital computer is one that keeps its programmed instructions, as well as its data, in read-write, random-access memory (RAM). Stored-program computers were an advancement over the program-controlled computers of the 1940s, such as the Colossus and the ENIAC, which were programmed by setting switches and inserting patch leads to route data and to control signals between various functional units. In the vast majority of modern computers, the same memory is used for both data and program instructions.
Hungarian American[1] mathematician who made major contributions to a vast range of fields,[2] including set theory, functional analysis, quantum mechanics, ergodic theory, continuous geometry, economics and game theory, computer science, numerical analysis, hydrodynamics (of explosions), and statistics, as well as many other mathematical fields. He is generally regarded as one of the foremost mathematicians of the 20th century.