Timeline of machine learning

From HandWiki
Short description: None

This page is a timeline of machine learning. Major discoveries, achievements, milestones and other major events in machine learning are included.

Overview

Decade Summary
pre-
1950		 Statistical methods are discovered and refined.
1950s Pioneering machine learning research is conducted using simple algorithms.
1960s Bayesian methods are introduced for probabilistic inference in machine learning.[1]
1970s 'AI winter' caused by pessimism about machine learning effectiveness.
1980s Rediscovery of backpropagation causes a resurgence in machine learning research.
1990s Work on Machine learning shifts from a knowledge-driven approach to a data-driven approach. Scientists begin creating programs for computers to analyze large amounts of data and draw conclusions – or "learn" – from the results.[2] Support-vector machines (SVMs) and recurrent neural networks (RNNs) become popular.[3] The fields of computational complexity via neural networks and super-Turing computation started.[4]
2000s Support-Vector Clustering[5] and other kernel methods[6] and unsupervised machine learning methods become widespread.[7]
2010s Deep learning becomes feasible, which leads to machine learning becoming integral to many widely used software services and applications. Deep learning spurs huge advances in vision and text processing.
2020s Generative AI leads to revolutionary models, creating a proliferation of foundation models both proprietary and open source, notably enabling products such as ChatGPT (text-based) and Stable Diffusion (image based). Machine learning and AI enter the wider public consciousness. The commercial potential of AI based on machine learning causes large increases in valuations of companies linked to AI.

Timeline

This list is incomplete; you can help by expanding it.
Year Event type Caption Event
1763 Discovery The Underpinnings of Bayes' Theorem Thomas Bayes's work An Essay towards solving a Problem in the Doctrine of Chances is published two years after his death, having been amended and edited by a friend of Bayes, Richard Price.[8] The essay presents work which underpins Bayes theorem.
1805 Discovery Least Square Adrien-Marie Legendre describes the "méthode des moindres carrés", known in English as the least squares method.[9] The least squares method is used widely in data fitting.
1812 Bayes' Theorem Pierre-Simon Laplace publishes Théorie Analytique des Probabilités, in which he expands upon the work of Bayes and defines what is now known as Bayes' Theorem.[10]
1913 Discovery Markov Chains Andrey Markov first describes techniques he used to analyse a poem. The techniques later become known as Markov chains.[11]
1943 Discovery Artificial Neuron Warren McCulloch and Walter Pitts develop a mathematical model that imitates the functioning of a biological neuron, the artificial neuron which is considered to be the first neural model invented.[12]
1950 Turing's Learning Machine Alan Turing proposes a 'learning machine' that could learn and become artificially intelligent. Turing's specific proposal foreshadows genetic algorithms.[13]
1951 First Neural Network Machine Marvin Minsky and Dean Edmonds build the first neural network machine, able to learn, the SNARC.[14]
1952 Machines Playing Checkers Arthur Samuel joins IBM's Poughkeepsie Laboratory and begins working on some of the very first machine learning programs, first creating programs that play checkers.[15]
1957 Discovery Perceptron Frank Rosenblatt invents the perceptron while working at the Cornell Aeronautical Laboratory.[16] The invention of the perceptron generated a great deal of excitement and was widely covered in the media.[17]
1963 Achievement Machines Playing Tic-Tac-Toe Donald Michie creates a 'machine' consisting of 304 match boxes and beads, which uses reinforcement learning to play Tic-tac-toe (also known as noughts and crosses).[18]
1967 Nearest Neighbor The nearest neighbour algorithm was created, which is the start of basic pattern recognition. The algorithm was used to map routes.[2]
1969 Limitations of Neural Networks Marvin Minsky and Seymour Papert publish their book Perceptrons, describing some of the limitations of perceptrons and neural networks. The interpretation that the book shows that neural networks are fundamentally limited is seen as a hindrance for research into neural networks.[19]
1979 Stanford Cart Students at Stanford University develop a cart that can navigate and avoid obstacles in a room.[2]
1979 Discovery Neocognitron Kunihiko Fukushima first publishes his work on the neocognitron, a type of artificial neural network (ANN).[20][21] Neocognition later inspires convolutional neural networks (CNNs).[22]
1981 Explanation Based Learning Gerald Dejong introduces Explanation Based Learning, where a computer algorithm analyses data and creates a general rule it can follow and discard unimportant data.[2]
1982 Discovery Recurrent Neural Network John Hopfield popularizes Hopfield networks, a type of recurrent neural network that can serve as content-addressable memory systems.[23]
1985 NETtalk A program that learns to pronounce words the same way a baby does, is developed by Terry Sejnowski.[2]
1986 Application Backpropagation Seppo Linnainmaa's reverse mode of automatic differentiation (first applied to neural networks by Paul Werbos) is used in experiments by David Rumelhart, Geoff Hinton and Ronald J. Williams to learn internal representations.[24]
1988 Universal approximation theorem Kurt Hornik (de) proves that standard multilayer feedforward networks are capable of approximating any Borel measurable function from one finite dimensional space to another to any desired degree of accuracy, provided sufficiently many hidden units are available.
1989 Discovery Reinforcement Learning Christopher Watkins develops Q-learning, which greatly improves the practicality and feasibility of reinforcement learning.[25]
1989 Commercialization Commercialization of Machine Learning on Personal Computers Axcelis, Inc. releases Evolver, the first software package to commercialize the use of genetic algorithms on personal computers.[26]
1992 Achievement Machines Playing Backgammon Gerald Tesauro develops TD-Gammon, a computer backgammon program that uses an artificial neural network trained using temporal-difference learning (hence the 'TD' in the name). TD-Gammon is able to rival, but not consistently surpass, the abilities of top human backgammon players.[27]
1995 Discovery Random Forest Algorithm Tin Kam Ho publishes a paper describing random decision forests.[28]
1995 Discovery Support-Vector Machines Corinna Cortes and Vladimir Vapnik publish their work on support-vector machines.[29]
1997 Achievement IBM Deep Blue Beats Kasparov IBM's Deep Blue beats the world champion at chess.[2]
1997 Discovery LSTM Sepp Hochreiter and Jürgen Schmidhuber invent long short-term memory (LSTM) recurrent neural networks,[30] greatly improving the efficiency and practicality of recurrent neural networks.
1998 MNIST database A team led by Yann LeCun releases the MNIST database, a dataset comprising a mix of handwritten digits from American Census Bureau employees and American high school students.[31] The MNIST database has since become a benchmark for evaluating handwriting recognition.
2002 Torch Machine Learning Library Torch, a software library for machine learning, is first released.[32]
2006 The Netflix Prize The Netflix Prize competition is launched by Netflix. The aim of the competition was to use machine learning to beat Netflix's own recommendation software's accuracy in predicting a user's rating for a film given their ratings for previous films by at least 10%.[33] The prize was won in 2009.
2009 Achievement ImageNet ImageNet is created. ImageNet is a large visual database envisioned by Fei-Fei Li from Stanford University, who realized that the best machine learning algorithms wouldn't work well if the data didn't reflect the real world.[34] For many, ImageNet was the catalyst for the AI boom[35] of the 21st century.
2010 Kaggle Competition Kaggle, a website that serves as a platform for machine learning competitions, is launched.[36]
2011 Achievement Beating Humans in Jeopardy Using a combination of machine learning, natural language processing and information retrieval techniques, IBM's Watson beats two human champions in a Jeopardy! competition.[37]
2012 Achievement Recognizing Cats on YouTube The Google Brain team, led by Andrew Ng and Jeff Dean, create a neural network that learns to recognize cats by watching unlabeled images taken from frames of YouTube videos.[38][39]
2012 Discovery Visual Recognition The AlexNet paper and algorithm achieves breakthrough results in image recognition in the ImageNet benchmark. This popularizes deep neural networks.[40]
2013 Discovery Word Embeddings A widely cited paper nicknamed word2vec revolutionizes the processing of text in machine learnings. It shows how each word can be converted into a sequence of numbers (word embeddings), the use of these vectors revolutionized text processing in machine learning.[41]
2014 Leap in Face Recognition Facebook researchers publish their work on DeepFace, a system that uses neural networks that identifies faces with 97.35% accuracy. The results are an improvement of more than 27% over previous systems and rivals human performance.[42]
2014 Sibyl Researchers from Google detail their work on Sibyl,[43] a proprietary platform for massively parallel machine learning used internally by Google to make predictions about user behavior and provide recommendations.[44]
2016 Achievement Beating Humans in Go Google's AlphaGo program becomes the first Computer Go program to beat an unhandicapped professional human player[45] using a combination of machine learning and tree search techniques.[46] Later improved as AlphaGo Zero and then in 2017 generalized to Chess and more two-player games with AlphaZero.
2017 Discovery Transformer A team at Google Brain invent the transformer architecture,[47] which allows for faster parallel training of neural networks on sequential data like text.
2018 Achievement Protein Structure Prediction AlphaFold 1 (2018) placed first in the overall rankings of the 13th Critical Assessment of Techniques for Protein Structure Prediction (CASP) in December 2018.[48]
2021 Achievement Protein Structure Prediction AlphaFold 2 (2021), A team that used AlphaFold 2 (2020) repeated the placement in the CASP competition in November 2020. The team achieved a level of accuracy much higher than any other group. It scored above 90 for around two-thirds of the proteins in CASP's global distance test (GDT), a test that measures the degree to which a computational program predicted structure is similar to the lab experiment determined structure, with 100 being a complete match, within the distance cutoff used for calculating GDT.[49]

See also

References

Citations

  1. Solomonoff, R.J. (June 1964). "A formal theory of inductive inference. Part II". Information and Control 7 (2): 224–254. doi:10.1016/S0019-9958(64)90131-7. 
  2. 2.0 2.1 2.2 2.3 2.4 2.5 Marr 2016.
  3. Siegelmann, H.T.; Sontag, E.D. (February 1995). "On the Computational Power of Neural Nets". Journal of Computer and System Sciences 50 (1): 132–150. doi:10.1006/jcss.1995.1013. 
  4. Siegelmann, Hava (1995). "Computation Beyond the Turing Limit". Journal of Computer and System Sciences 238 (28): 632–637. doi:10.1126/science.268.5210.545. PMID 17756722. Bibcode1995Sci...268..545S. 
  5. Ben-Hur, Asa; Horn, David; Siegelmann, Hava; Vapnik, Vladimir (2001). "Support vector clustering". Journal of Machine Learning Research 2: 51–86. 
  6. Hofmann, Thomas; Schölkopf, Bernhard; Smola, Alexander J. (2008). "Kernel methods in machine learning". The Annals of Statistics 36 (3): 1171–1220. doi:10.1214/009053607000000677. 
  7. Bennett, James; Lanning, Stan (2007). "The netflix prize". Proceedings of KDD Cup and Workshop 2007. https://www.cs.uic.edu/~liub/KDD-cup-2007/NetflixPrize-description.pdf. 
  8. Bayes, Thomas (1 January 1763). "An Essay towards solving a Problem in the Doctrine of Chance". Philosophical Transactions 53: 370–418. doi:10.1098/rstl.1763.0053. 
  9. Legendre, Adrien-Marie (1805) (in French). Nouvelles méthodes pour la détermination des orbites des comètes. Paris: Firmin Didot. p. viii. https://archive.org/details/bub_gb_FRcOAAAAQAAJ. Retrieved 13 June 2016. 
  10. O'Connor, J J; Robertson, E F. "Pierre-Simon Laplace". School of Mathematics and Statistics, University of St Andrews, Scotland. http://www-history.mcs.st-and.ac.uk/Biographies/Laplace.html. Retrieved 15 June 2016. 
  11. Langston, Nancy (2013). "Mining the Boreal North". American Scientist 101 (2): 1. doi:10.1511/2013.101.1. "Delving into the text of Alexander Pushkin's novel in verse Eugene Onegin, Markov spent hours sifting through patterns of vowels and consonants. On January 23, 1913, he summarized his findings in an address to the Imperial Academy of Sciences in St. Petersburg. His analysis did not alter the understanding or appreciation of Pushkin's poem, but the technique he developed—now known as a Markov chain—extended the theory of probability in a new direction.". 
  12. McCulloch, Warren S.; Pitts, Walter (December 1943). "A logical calculus of the ideas immanent in nervous activity". The Bulletin of Mathematical Biophysics 5 (4): 115–133. doi:10.1007/BF02478259. 
  13. Turing, A. M. (1 October 1950). "I.—COMPUTING MACHINERY AND INTELLIGENCE". Mind LIX (236): 433–460. doi:10.1093/mind/LIX.236.433. 
  14. Crevier 1993, pp. 34–35 and Russell & Norvig 2003, p. 17.
  15. McCarthy, J.; Feigenbaum, E. (1 September 1990). "In memoriam—Arthur Samuel (1901–1990)". AI Magazine 11 (3): 10–11. https://dl.acm.org/doi/10.5555/95618.95622. 
  16. Rosenblatt, F. (1958). "The perceptron: A probabilistic model for information storage and organization in the brain.". Psychological Review 65 (6): 386–408. doi:10.1037/h0042519. PMID 13602029. 
  17. Mason, Harding; Stewart, D; Gill, Brendan (6 December 1958). "Rival". The New Yorker. http://www.newyorker.com/magazine/1958/12/06/rival-2. Retrieved 5 June 2016. 
  18. Child, Oliver (13 March 2016). "Menace: the Machine Educable Noughts And Crosses Engine Read". http://chalkdustmagazine.com/features/menace-machine-educable-noughts-crosses-engine/#more-3326. Retrieved 16 Jan 2018. 
  19. Cohen, Harvey. "The Perceptron". http://harveycohen.net/image/perceptron.html. Retrieved 5 June 2016. 
  20. Fukushima, Kunihiko (October 1979). "位置ずれに影響されないパターン認識機構の神経回路のモデル --- ネオコグニトロン ---" (in Japanese). Trans. IECE J62-A (10): 658–665. https://search.ieice.org/bin/summary.php?id=j62-a_10_658. 
  21. Fukushima, Kunihiko (April 1980). "Neocognitron: A self-organizing neural network model for a mechanism of pattern recognition unaffected by shift in position". Biological Cybernetics 36 (4): 193–202. doi:10.1007/BF00344251. PMID 7370364. 
  22. Le Cun, Yann. Deep Learning. 
  23. Hopfield, J J (April 1982). "Neural networks and physical systems with emergent collective computational abilities.". Proceedings of the National Academy of Sciences 79 (8): 2554–2558. doi:10.1073/pnas.79.8.2554. PMID 6953413. Bibcode1982PNAS...79.2554H. 
  24. Rumelhart, David E.; Hinton, Geoffrey E.; Williams, Ronald J. (October 1986). "Learning representations by back-propagating errors". Nature 323 (6088): 533–536. doi:10.1038/323533a0. Bibcode1986Natur.323..533R. 
  25. Watksin, Christopher (1 May 1989). Learning from Delayed Rewards. http://www.cs.rhul.ac.uk/~chrisw/new_thesis.pdf. 
  26. Markoff, John (29 August 1990). "BUSINESS TECHNOLOGY; What's the Best Answer? It's Survival of the Fittest". New York Times. https://www.nytimes.com/1990/08/29/business/business-technology-what-s-the-best-answer-it-s-survival-of-the-fittest.html. Retrieved 8 June 2016. 
  27. Tesauro, Gerald (March 1995). "Temporal difference learning and TD-Gammon". Communications of the ACM 38 (3): 58–68. doi:10.1145/203330.203343. 
  28. Tin Kam Ho (1995). "Random decision forests". Proceedings of 3rd International Conference on Document Analysis and Recognition. 1. pp. 278–282. doi:10.1109/ICDAR.1995.598994. ISBN 0-8186-7128-9. 
  29. Cortes, Corinna; Vapnik, Vladimir (September 1995). "Support-vector networks". Machine Learning 20 (3): 273–297. doi:10.1007/BF00994018. 
  30. Hochreiter, Sepp; Schmidhuber, Jürgen (1 November 1997). "Long Short-Term Memory". Neural Computation 9 (8): 1735–1780. doi:10.1162/neco.1997.9.8.1735. PMID 9377276. 
  31. LeCun, Yann; Cortes, Corinna; Burges, Christopher. "THE MNIST DATABASE of handwritten digits". http://yann.lecun.com/exdb/mnist/. Retrieved 16 June 2016. 
  32. Collobert, Ronan; Benigo, Samy; Mariethoz, Johnny (30 October 2002). Torch: a modular machine learning software library. http://www.idiap.ch/ftp/reports/2002/rr02-46.pdf. Retrieved 5 June 2016. 
  33. "The Netflix Prize Rules". Netflix. Archived from the original on 3 March 2012. https://web.archive.org/web/20120303162455/http://www.netflixprize.com/rules. Retrieved 16 June 2016. 
  34. Gershgorn, Dave (26 July 2017). "ImageNet: the data that spawned the current AI boom — Quartz" (in en-US). https://qz.com/1034972/the-data-that-changed-the-direction-of-ai-research-and-possibly-the-world/. 
  35. Hardy, Quentin (18 July 2016). "Reasons to Believe the A.I. Boom Is Real". The New York Times. https://www.nytimes.com/2016/07/19/technology/reasons-to-believe-the-ai-boom-is-real.html. 
  36. "About". Kaggle Inc. https://www.kaggle.com/about. Retrieved 16 June 2016. 
  37. Markoff, John (16 February 2011). "Computer Wins on 'Jeopardy!': Trivial, It's Not". The New York Times: p. A1. https://www.nytimes.com/2011/02/17/science/17jeopardy-watson.html. 
  38. Le, Quoc V. (2013). "Building high-level features using large scale unsupervised learning". 2013 IEEE International Conference on Acoustics, Speech and Signal Processing. pp. 8595–8598. doi:10.1109/ICASSP.2013.6639343. ISBN 978-1-4799-0356-6. 
  39. Markoff, John (26 June 2012). "How Many Computers to Identify a Cat? 16,000". New York Times: p. B1. https://www.nytimes.com/2012/06/26/technology/in-a-big-network-of-computers-evidence-of-machine-learning.html. Retrieved 5 June 2016. 
  40. "The data that transformed AI research—and possibly the world" (in en). 2017-07-26. https://qz.com/1034972/the-data-that-changed-the-direction-of-ai-research-and-possibly-the-world. 
  41. PhD, Pedram Ataee (2022-07-03). "Word2Vec Models are Simple Yet Revolutionary" (in en). https://towardsdatascience.com/word2vec-models-are-simple-yet-revolutionary-de1fef544b87. 
  42. Taigman, Yaniv; Yang, Ming; Ranzato, Marc'Aurelio; Wolf, Lior (24 June 2014). "DeepFace: Closing the Gap to Human-Level Performance in Face Verification". Conference on Computer Vision and Pattern Recognition. https://research.facebook.com/publications/deepface-closing-the-gap-to-human-level-performance-in-face-verification/. Retrieved 8 June 2016. 
  43. Canini, Kevin; Chandra, Tushar; Ie, Eugene; McFadden, Jim; Goldman, Ken; Gunter, Mike; Harmsen, Jeremiah; LeFevre, Kristen et al.. "Sibyl: A system for large scale supervised machine learning". UC Santa Cruz. https://users.soe.ucsc.edu/~niejiazhong/slides/chandra.pdf. Retrieved 8 June 2016. 
  44. Woodie, Alex (17 July 2014). "Inside Sibyl, Google's Massively Parallel Machine Learning Platform". Datanami (Tabor Communications). http://www.datanami.com/2014/07/17/inside-sibyl-googles-massively-parallel-machine-learning-platform/. Retrieved 8 June 2016. 
  45. "Google achieves AI 'breakthrough' by beating Go champion". BBC. 27 January 2016. https://www.bbc.com/news/technology-35420579. Retrieved 5 June 2016. 
  46. "AlphaGo". Google Inc. https://www.deepmind.com/alpha-go.html. Retrieved 5 June 2016. 
  47. Vaswani, Ashish; Shazeer, Noam; Parmar, Niki; Uszkoreit, Jakob; Jones, Llion; Gomez, Aidan N.; Kaiser, Lukasz; Polosukhin, Illia (2017). Attention Is All You Need. 
  48. Sample, Ian (2 December 2018). "Google's DeepMind predicts 3D shapes of proteins". The Guardian. https://www.theguardian.com/science/2018/dec/02/google-deepminds-ai-program-alphafold-predicts-3d-shapes-of-proteins. 
  49. Eisenstein, Michael (23 November 2021). "Artificial intelligence powers protein-folding predictions". Nature 599 (7886): 706–708. doi:10.1038/d41586-021-03499-y. 

Works cited



Retrieved from "https://handwiki.org/wiki/index.php?title=Timeline_of_machine_learning&oldid=3370727"