Greek myths of Hephaestus and Pygmalion incorporate the idea of intelligent mechanisms. Something we would later call robots.
Egyptians invent the idea of thinking machines: citizens turn for advice to oracles, which are statues with priests hidden inside.
Babylonians develop a water clock named the “clepsydra.”
This water clock is considered one of the first “robotic” devices in the history of man kind. The water is recycled through a kind of siphoning system.
~700 – 800 BC
First symbolic mention of robots (automatae) appears in Homer’s Iliad(7) – or simulacra as they will be called later.
Here they are called “Golden Servants” made by the Greek mythological god Hephaestus: the binding god. His particular power’s are to mold metals into living beings made of precious metals. In Greek mythology, heavens are made of metal (bronze or gold) and Hephaestus is known as the celestial smith.
Archeologists will find hollow statues in which were hidden substances, believed to be potions, that should give mythological powers to these statues. A conclusion can be made that in the believe of the early Greek culture these statues would come, or were, alive and guard the premises when needed. Just like the Golden Servants that serve the god Hephaestus in his celestial forge are alive, given a soul by Hephaestus.
In the Phaedo and later works Plato expresses ideas, several millennia before the advent off the computer that are relevant to modern dilemmas regarding human thought and its relation to the mechanics of the machine.
Archytas of Tarentum, a friend of Plato, constructs a wooden pigeon whose movements are controlled by a jet of steam or compressed air.
The brilliant Greek mathematician, Archytas of Tarentum builds a mechanical bird dubbed “the Pigeon”, that is propelled by steam. It serves as one of histories earliest studies of flight, not to mention probably the first model airplane.
The Greek philosopher Aristotle writes…
“If every tool, when ordered, or even of its own accord, could do the work that befits it… then there would be no need either of apprentices for the master workers or of slaves for the lords.” …
hinting how nice it would be to have a few robots around.
The Greek inventor and physicist Ctesibus (‘ti sib ee uhs’) of Alexandria designs water clocks that have movable figures on them.
Water clocks are a big breakthrough for timepieces. Up until then the Greeks used hour glasses that had to be turned over, after all the sand ran through. Ctesibus’ invention changes this because it measures time as a result of the force of water falling through it at a constant rate. In general, the Greeks of this epoch are fascinated with automata of all kinds often using them in theater productions and religious ceremonies.
In China artisans develop elaborate automata, including an entire mechanical orchestra.
The Greek tradition is revived by Marcus Vitruvius Pollio (90 -20 BC, who describes several automata and developed the canon of proportions, which will become the basis of classical anatomical and architectural aesthetics. (5)(3)
One of the first stories of A.I., as a story is written of how a man falls in love with a statue he has created that has come to life.
100 AD app.
Hero of Alexandria detailed several automata that were used in theater and for religious purposes. He also designed automata that opened the gates on hydraulic principles.
A Chinese engineer and a Buddhist monk build the first true mechanical clock a water-driven device with an escapement that causes the clock to tick.
1200 AD app.
reproduction Topkapi Museum(9)
Arab authors also designed complex mechanical arrangements.
The most famous amongst them is Al-Jazari. He wrote Automata – which is considered the most important text for the study of the History of Technology. This book is richly illustrated and gives the state of the art of technology in the middle ages and shows how advanced technology in that time was compared with the western countries.(6)
Talking heads were said to have been created, Roger Bacon and Albert the Great reputedly among the owners.
Automated carillons begin to appear in the Netherlands.
robot and design by Leonardo da Vinci
In approximately 1495, before he began work on the Last Supper, Leonardo designed and possibly built the first humanoid robot in Western civilization.(4)
The robot, an outgrowth of his earliest anatomy and kinesiology studies recorded in the Codex Huygens, was designed according to the Vitruvian canon. This armored robot knight was designed to sit up, wave its arms, and move its head via a flexible neck while opening and closing its anatomically correct jaw. It may have made sounds to the accompaniment of automated drums. On the outside, the robot is dressed in a typical German-Italian suit of armor of the late fifteenth century. This robot would influence his later anatomical studies in which he modeled the human limbs with cords to simulate the tendons and muscles.(3)
In the 16th century Clockmakers extended their craft to creating mechanical animals and other novelties.
The technology of clockmaking has contributed considerably to the contruction of Atomata and calculators alike.
The first real android in human form that has been recorded is thought to have been built, approximately in this year, by Hans Bullmann at Nuernberg Germany.
He is said to have created quite a few androids – simulated people of which some can even play musical instruments to the delight of paying customers. (16)
Contemporary with Bullmann was Gianello Torriano of Cremona (1515-1585). One of his figures, that of a woman lute player, survived and is now in the Kunsthistorisches Museum in Vienna.(20)
Torriano, a lady figurine playing the lute. (28)
In his laboratory at Nuernberg, scholar Johann Müller, a.k.a. Regiomontanus, is reputed to have created an iron fly and an artificial eagle, both of which could take to the air. Supposedly with steam pressure.(16)
In England, John Dee creates a wooden beetle that can fly for an undergraduate production of Aristophanes’ Pax.(16)
wooden monk automata apr. 1560
Here is a fine example of the technology of automata in the sixteenth century.
Shown here is a wooden monk, apr 30 centimeters in height, with a crude lever and joints mechanism. The purpose of this puppet will remain guesswork, and how long it took to create it too. But with our contemporary tooling it would certainly take a few months to get this intricate machinery working. A scientist in historic tooling would probably give it a year, but to our opinion at least 2 years of trying and retrying. This proves that making automata still went on during the dark ages. (the above pictures are taken at the Deutsches Museum at Munich in Germany, and the statuette stands behind very thick glass, that’s why you see some reflection in the pictures)
picture from: Dix livres de chirurgie (Paris 1564)
In Dix livres de chirurgie (Paris 1564) Pare Ambroise publishes a design of a mechanical hand. Made from the real thing enforced with mechanical “muscles”.
You’ll observe that comparing the two examples given here and above the metal work is of a comparable level. This level of mechanics in this epoch opens enormous possibilities. So why did developments stop? In Gaby Wood’s book Living Dolls (see library) some indication is given: superstition. Also according to Wood: inventors dealing with human like automatons had to be very careful. For the clerics closely watched these developments, an inquisition counsel was always nearby. Not in all countries though.
Rabbi Loew of Prague is said to have invented the Golem, a clay man brought to life.
It is in the 18th century, halfway through the Edo period, that Japan sees the debut of puppets, called “karakuri-ningyo,” with mechanisms fitted inside that makes them move by themselves.
At about the same time, similar mechanical dolls, called “auto-mata”, appear in Europe. As for the Japanese puppets, their initial development dates back to the middle of the 16th century when “Nanban (foreign) culture” made its way to the country near the end of the Muromachi Era. A close examination of the puppet’s mechanism points to the particular influence of the clock making technology of Europe brought to Japan by Francis Xavier and other Jesuit missionaries.
At the Heilbrunn chateau in Germany, a mechanical theatre is created featuring 119 animated figures that perform a play about village life to the accompaniment of a water-powered organ.(16)
While training as a Jesuit, Jacques Vaucanson creates flying angels which cause him to be thrown out of the order. (16)
The now famous word “android” is coined after German philosopher and alchemist Albertus Magnus who attempts to create an artificial being.
French inventor Jacques Vaucanson creates several robotic beings, including a human-sized, flute-playing android.
construction and detail of Vaucanson’s Duck 1738
Jacques de Vaucanson begins building automata in Grenoble, France.
He builds three in all. His first was the flute player that could play twelve songs. This was closely followed by his second automaton that played a flute and a drum or tambourine, but by far his third was the most famous of them all. The duck was an example of Vaucanson’s attempt at what he called “moving anatomy”, or modeling human or animal anatomy with mechanics.” The duck moved, quacked, flapped it’s wings and even ate and digested food.
Knaus writing automata
Actually the very first writing automata, in the western world, was developed by Knaus in 1753.
If you look closely to the top of this contraption you will observe some writing on a white rectangular piece of paper. And as was usual in these centuries, the ornaments were almost as important as the functionality of the machine itself.
German Inventor Friedrich von Knauss creates an android able to hold a pen and write a segment of up to 107 words.
Pierre Jacquet-Droz starts to create life-like androids modeled after writers, artists and musicians.
Pierre and Henry Louis Jaquet-Droz (Swiss) invented the first automaton that could write.
Soon after that they build another automaton that draws a portrait of King Louis XV. Taking the word ‘robot’ in a broad sense, we might say that their machines are some of the first working robots. They create three dolls, each with a unique function. One can write, another plays music, and the third draws pictures as the one shown here.
Louis XV drawing from a later draughtsman(2)
At the museum d’Arts et d’Histore at Neuchâtel, Switzerland, public demonstrations of the Jaquet-Droz automations can be attended. Demonstrations are held at the first sunday of each month at 14, 15, and 16 hours. Price is included in the admission of the museum.(24) The above automata draws 4 sketches, each sketch is drawn in about 3 minutes.
A nice book on this type of early automatons is written by Gaby Woods at least the fist few chapters, after that the book is less to the point.
Joseph Jacquard builds an automated loom that is controlled with punched cards. Punch cards are later used as an input method for some of the 20th centuries earliest computers.
front and back of Kaufmann’s Trumpeter 1810 (10)
The Mechanical Trumpeter constructed by Friedrich Kaufmann in 1810.
This is an example of a program (e.g. stepped drum) mounted into an automata to play a tune, like the European street organs. The notches mounted on the drum activated valves that let the air pass by 12 tongues. Which produced a kind of modulated sound. This sound will be modulated through a trumpet so it does sound like a trumpet The stepped drum and the bellows are powered by a spring mechanism that need to be wound up, observe the crank laying at the bottom. The height of this automata is apr. 180 cm.
Mary Shelley writes the famous novel “Frankenstein.” which is about a frightening artificial life form created by Dr. Frankenstein.
The Frankenstein complex still resides in the mind of the general public. Pointing towards the possible mishap that will undoubtedly be caused by malfunction of robots and alike and that all machines will eventually turn against human kind. Later fears, misshapen, accidents and even novels concerning artificial life forms will deal with this so called “Frankenstein complex”. In the mind of mankind robots are bound to cause accidents or other imaginary mischief.
Charles Babbage demonstrates a prototype of his “Difference Engine” to the Royal Astronomical Society.
He continues his work by designing an even more ambitious project “the Analytical Engine” that reportedly was to use punch cards inspired by Joseph Jacquard’s invention. During his lifetime he never produces a functional version of any of the machines. Despite this shortcoming he is often heralded as the “Father of the Computer” and his work lives on as the foundation for the binary numbering system that is the basis of modern computers. A computer will form the “brain” of future robots.
Edison’s “invention laboratorium” is producing a talking-doll.
Nikolai Tesla creates the first remote-controlled vehicles.
Seward Babbitt (USA) designs a motorized crane with gripper to remove ingots from a furnace. (23)
Nikola Tesla builds and demonstrates a remote controlled robot boat at Madison Square Garden.
The word ROBOT is used for the first time in the context of mechanical people in a play called “R.U.R” (Rossum’s Universal Robots) by Czech dramatist Karel Capek.
These are intelligent machines meant to serve their human makers. But the play ends dramatic as robots took over the world and destroyed humanity. The Frankenstein syndrome invented before he was even there! Karel Capek (Czech) called these powerful beings “robota” meaning forced and slavishly work. He distinguishes the robot from man by the absence of emotion .(12)
picture courtesy Augusto Cesar B. Areal (13)
Fritz Lang’s movie “Metropolis” is released.
“Maria” the female robot in the film is the first robot to be projected on the silver screen. The android is built in the form of its creator’s wife. This movie is commonly known as the precursor to Star War’s C-3PO.(19)
Alan Turing introduces the concept of a theoretical computer called the Turing Machine.
It is a fundamental advance in computer logic and also spawns new schools in Mathematics. He completes his seminal paper On Computable Numbers, which paves the way for modern computers.
The first programmable paint-spraying mechanism is designed by Americans Willard Pollard and Harold Roselund for the DeVilbiss Company.
1929-1938 Psychologists Clark Hull, Thomas Ross, develop the Hypothetico-Deductive System, in an attempt to design learning robots.
Isaac Asimov (1920-1992) produces a series of short stories about robots starting with “A Strange Playfellow” (later renamed “Robbie”) for Super Science Stories magazine.
The story is about a robot and its affection for a child that it is bound to protect. Over the next 10 years he produces more stories about robots that are eventually recompiled into the volume “I, Robot” in 1950. (14)
Asimov is generally credited with the popularization of the term “Robotics” which was first mentioned in his story “Runaround” in 1942.
But probably Isaac Asimov’s most important contribution to the history of the robot is the creation of his Three Laws of Robotics:
1. A robot may not injure a human being, or, through inaction, allow a human being to come to harm.
2. A robot must obey the orders given it by human beings except where such orders would conflict with the First Law.
3. A robot must protect its own existence as long as such protection does not conflict with the First or Second Law.
Asimov later adds a “zeroth law” to the list:
0. A robot may not injure humanity, or, through inaction, allow humanity to come to harm.
Warren McCulloch and Walter Pitts do pioneering work on neural networks that can learn about the world in much the same way that we do.
George Devol patents a playback device for controlling machines, using magnetic recording.
Concept of a stored program (von Neumann) and generic re-programmability of computers.
The first general-purpose digital computer, dubbed Whirlwind, solves its first problem at M.I.T.(23)
Norbert Wiener, a professor at M.I.T., publishes Cybernetics or “Control and Communication in the Animal’, a book which describes the concept of communications and control in electronic, mechanical, and biological systems.
British robotics pioneer William Grey Walter creates autonomous machines called Elmer and Elsie that mimic lifelike behavior with very simple circuitry.
Alan Turing publishes Computing Machinery and Intelligence in which he proposes a test to determine whether or not a machine has gained the power to think for itself.
It becomes known as the “Turing Test”. Since then each year a contest is held between various software developers to determine how close they have come to the true Turing Machine.
The Day the Earth Stood Still premieres in theaters. The movie features an alien named Klaatu and his robot Gort.
In France, Raymond Goertz designs the first tel operated articulated arm for the Atomic Energy Commission.
The design is based entirely on mechanical coupling between the master and slave arms (using steel cables and pulleys). Derivatives of this design are still seen in places where handling of small nuclear samples is required. This is generally regarded as the major milestone in force feedback technology.
The first NC (numerically controlled) machine is built.
George Devol and Joe Engleberger design the first programmable robot “arm” and uses the term Universal Automation for the first time. Thus planting the seed for the name of his future company – Unimation.
Alan Newell and Herbert Simon create the Logic Theorist, the first “expert system”. It is used to help solve difficult math problems.
Marvin Minsky and John McCarthy organize a conference in Dartmouth, Massachusetts, US, which brings together the leading figures in the field of robotics and machine research. The conference coins the phrase “artificial intelligence”.(16)
Squee, the electronic robot squirrel. The two phototubes or “eyes” are at the top of the steering post; the scoop which opens and closes, or “hands”, is at the front.
Squee (named after “squirrel”) is an electronic robot squirrel. It contains four sense organs (two phototubes, two contact switches), three acting organs (a drive motor, a steering motor, and a motor which opens and closes the scoop or “hands”), and a small brain of half a dozen relays. It will hunt for a “nut”. The “nut” is a tennis ball designated by a member of the audience who steadily holds a flashlight above the ball, pointing the light at Squee. Then Squee approaches, picks up the “nut” in its “hands” (the scoop), stops paying attention to the steady light, sees in stead a light that goes on and off 120 times a second shining over its “nest”, takes the “nut” to its “nest”, there leaves the nuts, and then returns to hunting more “nuts”. Data: completed; rather well finished but not professionally; 75% reliable; maintenance, difficult; our costs, about $3,000. (9)
George Devol and Joseph Engelberger formed the world’s first robot company.
George Devol and Joseph F. Engelberger meet at a cocktail party and during the evening exchange some serious ideas:
* 50 percent of the people who work in factories are really putting and taking.
* Why are machines made to produce only specific items?
* How about approaching manufacturing the other way around, by designing machines that could put and take anything?
As a result of this discussion the same year Devol and Engelberger form the world’s first robot company. It is called Unimation, Inc.
Thanks to a huge effort on Devol’s part along with the management skill of Joseph Engelberger Devol’s robot evolves into the Unimate. It combines industrial manipulator technology and nascent computer control technology. Their first robot is a material handling robot and is soon followed by robots for welding and other applications.(10)(**)
The term “artificial intelligence” is coined.
Aided by a grant from the Rockefeller Foundation John McCarthy, Marvin Minsky, Nat Rochester and Claude Shannon organize The Dartmouth Summer Research Project on Artificial Intelligence at Dartmouth College.
Servomechanisms Laboratory at MIT demonstrates one of the first practical application to computer-assisted manufacturing.
The lab developed a specific language for this tool called: “Automatically Programmed Tools” (APT). This language is used to instruct milling machine operations. While demonstrating the language the machine produced an ashtray for each visitor.(25)
John McCarthy and Marvin Minsky start the Artificial Intelligence Laboratory at the Massachusetts Institute of Technology (MIT).
Computer-assisted manufacturing was demonstrated at the Servomechanisms Lab at MIT.
Unimation is purchased by Condec Corporation and development of Unimate Robot Systems begins.(10)
American Machine and Foundry, later known as AMF Corporation, markets the first cylindrical robot, called the Versatran, designed by Harry Johnson and Veljko Milenkovic.
Heinrich Ernst develops the MH-1, a computer operated mechanical hand at MIT.
(25)Unimate industrial robot
The assembly line robot Unimate is controlled step-by-step by commands stored on a magnetic drum, the 4,000-pound arm sequenced and stacked hot pieces of die-cast metal. Unimate is the brainchild of Joe Engelberger and George Devol, and originally automated the manufacture of TV picture tubes.
The first industrial arm robot – the Unimate – is introduced.
It is designed to complete repetitive or dangerous tasks on a General Motors production line. This manipulator is the first of many Unimates to be deployed.
John McCarthy leaves MIT to start the Artificial Intelligence Laboratory at Stanford University.
The first artificial robotic arm to be controlled by a computer is designed at Rancho Los Amigos Hospital in Downey, California as a tool for the handicapped.
The Rancho Arm six joints gave it the flexibility of a human arm. Acquired by Stanford University in 1963, it holds a place among the first artificial robotic arms controlled by a computer.
Artificial intelligence research laboratories are opened at M.I.T., Stanford Research Institute (SRI), Stanford University, and the University of Edinburgh.
C&D Robotics founded.
Carnegie Mellon University establishes the Robotics Institute.
Homogeneous transformations applied to robot kinematics – this remains the foundation of robotics theory today
DENDRAL is the first expert system or program designed to execute the accumulated knowledge of subject experts.
An artificial intelligence program named ELIZA is created at MIT by Joseph Weizenbaum.
ELIZA functions as a computer psychologist that manipulates its users statements to form questions. Weizenbaum is disturbed at how quickly people put faith in his little program.
The Stanford Research Institute creates Shakey.
The first mobile robot that can reason about its surroundings. Five years later, funding is cancelled when the shortcomings of the machine become apparent.(16)
Richard Greenblatt writes, MacHack, a program that plays chess.
In response to a recent article written by Hurbert Dreyfus where he suggests, as a critique to efforts in artificial intelligence, that a computer program could never beat him in a game of chess. When the program is finished and Dreyfus is invited to play the computer he leads for most of the game but ultimately loses in the end in a close match. Greenblatt’s program would be the foundation for many future chess programs, ultimately culminating in Big Blue the chess program that beats chess Grand Master Gary Kasparov.
Japan imports the Versatran robot from AMF (the first robot imported into Japan).
Stanley Kubrick makes Arthur C. Clark’s, 2001: A Space Odyssey into a movie.
It features HAL, an onboard computer that decides it doesn’t need its human counterparts any longer. Hear HAL by clicking here.
Kawasaki licenses hydraulic robot design from Unimation and starts production in Japan.
The octopus-like wall mounted tentacle Arm is developed by Marvin Minsky.
Its twelve joints enabled the arm to go around corners. A PDP-6 computer controls the arm, powered by hydraulic fluids. The arm could lift the weight of a person.
Victor Scheinman, a Mechanical Engineering student working in the Stanford Artificial Intelligence Lab (SAIL) creates the Stanford Arm.
The arm’s design becomes a standard and is still influencing the design of robot arms today.
Victor Scheinman´s Stanford Arm made a breakthrough as the first successful electrically powered, computer-controlled robot arm. By 1974, the Stanford Arm could assemble a Ford Model T water pump, guiding itself with optical and contact sensors. The Stanford Arm led directly to commercial production. Scheinman went on to design the PUMA series of industrial robots for Unimation, robots used for automobile assembly and other industrial tasks.
picture right courtesy SRI international
Shakey from SRI, Menlo Park USA, can see and avoid obstacles. Shakey is introduced as the first mobile robot controlled by artificial intelligence. It is produced by SRI International.
SRI International´s Shakey is the first mobile robot controlled by artificial intelligence. And equipped with sensing devices driven by a problem-solving program called STRIPS, the robot finds its way around the halls of SRI by applying information about its environment to a route. Shakey uses a TV camera, laser range finder, and bump sensors to collect data, which it then transmits to a DEC PDP-10 and PDP-15. The computer radio’s back commands to Shakey — who then moves at a speed of 2 meters per hour.(26)
Professor Victor Scheinman of Stanford University designs the Standard Arm. Today, its kinematic configuration remains known as the Standard Arm.
Stanford University produces the Stanford Cart. It is designed to be a line follower but can also be controlled from a computer via radio link.
Cincinnati Milacron Corporation releases the T3, (The Tomorrow Tool) the first commercially available minicomputer-controlled industrial robot (designed by Richard Hohn).
The AI department at Edinburgh, UK, shows off Freddy II, a robot that could assemble objects automatically from a heap of parts.(16)
At the Waseda university in Japan the Wabot-1 is built.
This is the first full-scale anthropomorphic robot built in the world. It consists of a limb control system, a vision system, and a conversation system. The Wabot-1 is able to communicate with a person in Japanese and to measure distances and directions to the objects using external receptors, artificial ears and eyes, and an artificial mouth. The Wabot-1 walkes with his lower limbs and is able to grip and transport objects with hands that used tactile sensors.(2)
Scheinman Silver Arm 1974
Victor Scheinman forms his own company and starts marketing the Silver Arm. It is capable of assembling small parts together using feedback from touch and pressure sensors. (14)
Victor Scheinman develops the Programmable Universal Manipulation Arm (Puma), which becomes widely used as industrial robots.(16)
Unimation will purchase Vicarm Inc. (1977) and develop The PUMA (Programmable Universal Machine for Assembly) robot to be marketed in 1979.(23)
Shigeo Hirose designs the Soft Gripper at the Tokyo Institute of Technology. It is designed to wrap around an object in snake like fashion.(14)
Robot arms are used on Viking 1 and 2 space probes. Vicarm Inc. incorporates a microcomputer into the Vicarm design.
Star Wars is released. George Lucas’ movie about a universe governed by the force introduces watchers to R2-D2 and C-3PO.
The movie creates the strongest image of a human future with robots since the 1960’s and inspires a generation of researchers.(14)
ASEA, a European robot company, offers two sizes of electric powered industrial robots. Both robots use a microcomputer controller for programming and operation.
Unimation purchases Vicarm Inc.
Using technology from Vicarm, Unimation develops the PUMA (Programmable Universal Machine for Assembly). The PUMA can still be found in many research labs today.
Brooks Automation founded
The Robotics Institute at Carnegie Mellon University is established.
Sankyo and IBM market the SCARA (selective compliant articulated robot arm) developed at Yamanashi University in Japan
The Stanford Cart is rebuilt by Hans Moravec in 1977.
He adds a more robust vision system allowing greater autonomy in navigating across a room full of obstacles. These are some of the first experiments with 3D environment mapping. The Standford Cart crosses a chair-filled room without human assistance. The cart has a tv camera mounted on a rail which takes pictures from multiple angles and relays them to a computer. The computer analyzes the distance between the cart and the obstacles.
Stanford cart 1979
Seymour Papert publishes Mindstorms: Children, Computers, and Powerful Ideas where he advocates constructivism, or learning through doing.
Takeo Kanade builds the direct drive arm. It is the first to have motors installed directly into the joints of the arm. This development makes joins faster and much more accurate than previous robotic arms.
CRS Robotics Corp. founded.
“A new life awaits you on the Off-World colonies.” Blade Runner is released.
This Ridley Scott film is based on the Philip K. Dick story “Do Androids Dream of Electric Sheep?” and starred Harrison Ford as Rick Deckard a retired Blade Runner that hunted Replicants (or illegal mutinous androids).(14)
Fanuc of Japan and General Motors form a joint venture: GM Fanuc. The new company is going to market robots in North America.
Film “Bladerunner” debuts as a story about androids that are “more human than human.”
Adept Technology founded.
Joseph Engelberger starts Transition Robotics, later renamed Helpmates, to develop service robots.
Doug Lenat kicks off the EnCYClopedia project to create a database of common sense to help robots understand our world.
First started at Microelectronics and Computer Technology Corporation (MCC) where Professor Lenat worked as a principle scientist for 10 years. This project collects all over the world knowledge based on “microtheories” (R.V. Guha). Each microtheory is involved a human activity: shopping, swimming, etc. Many major corporations such as Bellcore, Apple, Kodak, DEC, AT&T, Microsoft, and Interval Research are the supporters of this project.(18)
LEGO and the MIT Media Lab collaborate to bring the first LEGO based educational products to market.
LEGO tc Logo is used by in the classrooms of thousands of elementary school teachers.
Honda begins a robot research program that’s starts with the premise that the robot “should coexist and cooperate with human beings, by doing what a person cannot do and by cultivating a new dimension in mobility to ultimately benefit society.”
With Unimation license terminated, Kawasaki develops and produces its own line of electric robots.
Automated selling of shares almost causes a (Wall street, USA) stock market meltdown.
Stäubli Group purchases Unimation from Westinghouse.
A walking robot named Genghis is unveiled by the Mobile Robots Group at MIT. It becomes known for the way it walks, popularly referred to as the “Genghis gait”.
At MIT Rodney Brooks and A. M. Flynn publish the paper “Fast, Cheap and Out of Control: A Robot Invasion of the Solar System” in the Journal of the British Interplanetary Society.
The paper changes rover research from building the one, big, expensive robot to building lots of little cheap ones. The paper also makes the idea of building a robot somewhat more accessible to the average person.
Academics start to concentrate on small, smart useful robots rather than simulated people.(17)
Dr. Seymour Papert becomes the LEGO Professor of Learning Research.
Computer Motion founded.
Barrett Technology founded
ABB of Switzerland acquires Cincinnati Milacron (creator of PUMA). Most small robot manufacturers go out of business leaving only a few that now produce well developed industrial units.
In an attempt to build a radio controlled vacuum cleaner Marc Thorpe has the idea to start a robot combat event.
Dr. John Adler came up with the concept of the CyberKnife a robot that images the patient with x-rays to look for a tumor and delivering a pre-planned dose of radiation to the tumor when found.
Dante an 8-legged walking robot developed at Carnegie Mellon University descends into Mt. Erebrus, Antarctica.
Its mission is to collect data from a harsh environment similar to what we might find on another planet. The mission fails when, after a short 20 foot decent, Dante’s tether snaps dropping it into the crater.
picture courtesy Seiko Epson Co.
Seiko Epson develops a micro robot called Monsieur, the world’s smallest micro robot as certified by the Guinness Book of World Records.
Sensable Technologies founded.
Carnegie Mellon University (CMU) Robotics Institute’s Dante II, a more robust version of its predecessor, descends into the crater of Alaskan (USA) volcano Mt. Spurr to sample volcanic gases. The mission is considered a success.
Marc Thorpe starts Robot Wars at Fort Mason center in San Francsico, CA.
The second annual Robot Wars event is held at Fort Mason Center, San Francisco, CA.
Intuitive Surgical formed by Fred Moll, Rob Younge and John Freud to design and market surgical robotic systems. Founding technology based on the work at SRI, IBM and MIT.
picture courtesy MIT (17)
A RoboTuna (fish) is designed and built by David Barrett for his doctoral thesis at MIT.
It is used to study the way fish swim. Michael S. Triantafyllou a professor in the Department of Ocean Engineering is leading the research team. The fish is not a free swimming fish, that will take another few years or research to achieve. A project taken up by John Kumph (2004) (17)
Chris Campbell and Dr. Stuart Wilkinson ( University of South Florida in Tampa, USA) turn a brewing accident into inspiration at the University of South Florida.
The result is the Gastrobot, a robot that digests organic mass to produce carbon dioxide that is then used for power. They call their creation the “flatulence engine.” Later a more conventional nickname is given: “Chew Chew”.
Honda unveils the P-2 (prototype 2), a humanoid robot that can walk, climb stairs and carry loads.
picture courtesy NASA 2001
The first node of the International Space Station is placed in orbit. Over the next several years more components will join it, including a robotic arm designed by Canadian company MD Robotics.
Honda showcases the P3, the 8th prototype in a humanoid design project started in 1986.
Computer programs, called “web bots”, become widely used on the web to delve for information.
Web bots are build around a core that presumably has limited intelligence, or better ‘smartness’, clever algorithms to decide the relevance of information against what a user has requested to search for (information). Webbots are autonomous agents that seek their own way on or through the Internet without human intervention.
The first RoboCup football tournament is held in Nagoya, Japan. (16)
May, World chess champion Garry Kasparov loses to IBM’s Deep Blue supercomputer.
July, The Pathfinder Mission lands on Mars.
Its robotic rover Sojourner, rolls down a ramp and onto Martian soil in early July. It continues to broadcast data from the Martian surface until September. NASA’s Mars PathFinder mission captures the eyes and imagination of the world as PathFinder lands on Mars and the Sojourner rover robot sends back images of its travels on the distant planet. Over a few million visitors bombard the web server of NASA’s per day necessitate NASA to set up mirror sites all over the world.
Tiger Electronics introduces the Furby for the Christmas toy market.
It quickly becomes “the toy” to get for the season. Using a variety of sensors this “animatronic pet” can react to its environment and communicate using over 800 phrases in English and their own language “Furbish”.
LEGO releases their first Robotics Invention SystemTM 1.0. LEGO names the product line MINDSTORMS after Seymour Papert’s seminal work of 1980.
Scottish hotel owner Campbell Aird is fitted with the world’s first bionic arm.
August, Cynthia Breazeal at MIT starts work on the Kismet robot, which can mimic the emotional range of a baby.(16)
October, Nasa launches the Deep Space 1 autonomous spacecraft which will test technologies to be used in future missions crewed and conducted solely by robots. (16)
Aibo, Sony, Japan(8)
May, Sony builds Aibo, K9 the next generation. One of the first robots intended for the consumer market. It reacts on sounds and has some sort of preprogrammed behavior. It sells out within 20 minutes of going on sale.
LEGO releases The Robotics Discovery Set, Droid Developer Kit and the Robotics Invention System 1.5.
Personal Robots releases the Cye robot that can be used to perform a variety of household chores.
Honda debuts a new humanoid robot ASIMO, the next generation of its series of humanoid robots.
The Battlebots event is held in Las Vegas, Nevada.
LEGO releases the MINDSTORMS Robotics Invention SystemTM 2.0
October, The UN estimates that there are 742,500 industrial robots in use worldwide. More than half of these are being used in Japan.(16)
November 11, Sony unveils humanoid robots, dubbed Sony Dream Robots (SDR), at Robodex.
November, Computational neurobiologist Sandro Mussa-Ivaldi, from the Northwestern University Medical School in Chicago, US, hooks up a lamprey brain to sensors in order to control a robot. (16)
LEGO releases the MINDSTORMS Ultimate Builder’s Set
Sony’s AIBO 2nd generation
Sony releases the second generation of its Aibo robot dog.
ISS SSRMS; picture: courtesy MD Robotics 2004
Built by MD Robotics of Canada, the Space Station Remote Manipulator System (SSRMS) is successfully launched into orbit and begins operations to complete assembly of International Space Station.
April, The Global Hawk robotic spy plane charts its own course over a distance of 13,000 km (8,000 miles) between California, US, and Southern Australia.(16)
August, the FDA clears the CyberKnife to treat tumors anywhere in the body.
Asimo, Honda Japan (7)
Honda’s Asimo was the first robot that could walk independently with relatively smooth movements and could climb the stairs. Honda’s ASIMO robot rings the opening bell at the New York Stock Exchange.
SONY releases the AIBO ERS-7 it’s 3rd generation robotic pet.
Epson unveils the Monsieur II-P in April 2003.
Miyazawa says, “The next challenge is to test the possibilities of microrobots in another dimension–the air. In many ways it is a natural progression from Monsieur II-P,” which moves freely along the ground.
courtesy Seiko Epson Co.
Epson releases the smallest robot.
Weighing 0.35 ounces (10 grams) and measuring 2.8 inches (70 millimeters) in height, the Micro Flying Robot is unveiled as the world’s lightest and smallest robot helicopter. The company hopes it will be used as a “flying camera” during natural disasters. This prototype hardly flies more than a few meters though but the object is intended as a show case to what the company is capable of.
Researchers at Cornell University claim to have built the first self-replicating robot.
The array of computerized cubes illustrates the principles of self-replication, says Hod Lipson, a professor of mechanical and aerospace engineering at Cornell who led the team that designed the repli-bots. Each “robot” is a small tower of computerized cubes linked by magnets. The magnets allow the cubes to link up with or detach themselves from one another. One stack of cubes puts its “head” on the table, then it picks up a new cube and sets it on this “seed.” It repeats the process to build its sibling. Moreover, the new robot begins to assist the old in the building process.(27)
pictures: courtesy Cornell university 2005
You can see this replicator in action at: http://www.mae.cornell.edu/ccsl/research/selfrep/video/4x4ht4a.wmv
Fish seem very promising subjects to test robotic navigation.
Since October 6 in London Aquarium’s at County Hall three attractive looking robotic fish are swimming in a specially-designed tank.
They have been produced by Professor Huosheng Hu and his human-centred robotics team of the Department of Computer Science at the University of Essex. Professor Hu’s team have been working with the London Aquarium for three years to develop a biologically inspired robotic fish which mimic the undulating movement of nature’s fish species – aiming for the speed of the tuna; the acceleration of a pike, and the navigating skill of the eel.
The robotic fish have sensor-based controls and autonomous navigation capabilities – they can find their own way around the tank safely, avoiding the objects, and react to their environment. According to Professor Hu, the aim of the project is to bring the public in direct contact with robots, increasing their understanding of science and technology: ‘This work has many real-world applications including seabed exploration, detecting leaks in oil pipelines, mine countermeasures, and improving the performance of underwater vehicles.’
The Aquarium’s marine experts have worked with the robotics team to share their knowledge of the behavior and movement of a wide variety of fish, and have provided the facilities within the Aquarium for the robotics team to study many species in great detail.(1)
Footnotes & References
1.ref: http://www.gizmag.co.uk/go/4725/ accessed 11 october 2005
2.http://www.humanoid.rise.waseda.ac.jp/booklet/booklet2000.html last accessed 20061111
7.asimo pictures courtesy Honda Japan
8.picture THOCF taken at Harrods, London 2002
9.text and picture courtesey of http://www.blinkenlights.com/classiccmp/berkeley/report.html; accessed 20051128
10.http://en.wikipedia.org/wiki/George_Devol, last access 20060222
14.ref: http://www.megagiant.com/history.html last accessed 8 july 2004
16.BBC news, news.bbc.co.uk last accessed 10/10/2001
17.ref: web.mit.edu/towtank/www/Tuna/Tuna1/tuna1.html accessed 20041121; pictures from: http://web.mit.edu/towtank/www/Tuna/Tuna1/pictures.html
23.Mechatronics and Robotics May 19, 2004 7
25.Picture courtesy http://www.computerhistory.org; digitally enhanced by THOCF,