Timeline of information theory

From HandWiki
Short description: None

A timeline of events related to Red pog.svg information theory, 12px quantum information theory and statistical physics, 12px data compression, Purple pog.svg error correcting codes and related subjects.

  • 1872 Orange pog.svg – Ludwig Boltzmann presents his H-theorem, and with it the formula Σpi log pi for the entropy of a single gas particle
  • 1878 Orange pog.svg – J. Willard Gibbs defines the Gibbs entropy: the probabilities in the entropy formula are now taken as probabilities of the state of the whole system
  • 1924 Red pog.svgHarry Nyquist discusses quantifying "intelligence" and the speed at which it can be transmitted by a communication system
  • 1927 Orange pog.svg – John von Neumann defines the von Neumann entropy, extending the Gibbs entropy to quantum mechanics
  • 1928 Red pog.svg – Ralph Hartley introduces Hartley information as the logarithm of the number of possible messages, with information being communicated when the receiver can distinguish one sequence of symbols from any other (regardless of any associated meaning)
  • 1929 Orange pog.svg – Leó Szilárd analyses Maxwell's Demon, showing how a Szilard engine can sometimes transform information into the extraction of useful work
  • 1940 Red pog.svg – Alan Turing introduces the deciban as a measure of information inferred about the German Enigma machine cypher settings by the Banburismus process
  • 1944 Red pog.svgClaude Shannon's theory of information is substantially complete
  • 1947 Purple pog.svg – Richard W. Hamming invents Hamming codes for error detection and correction (to protect patent rights, the result is not published until 1950)
  • 1948 Red pog.svg – Claude E. Shannon publishes A Mathematical Theory of Communication
  • 1949 Red pog.svg – Claude E. Shannon publishes Communication in the Presence of NoiseNyquist–Shannon sampling theorem and Shannon–Hartley law
  • 1949 Red pog.svg – Claude E. Shannon's Communication Theory of Secrecy Systems is declassified
  • 1949 Green pog.svg – Robert M. Fano publishes Transmission of Information. M.I.T. Press, Cambridge, Massachusetts – Shannon–Fano coding
  • 1949 Green pog.svg – Leon G. Kraft discovers Kraft's inequality, which shows the limits of prefix codes
  • 1949 Purple pog.svg – Marcel J. E. Golay introduces Golay codes for forward error correction
  • 1951 Red pog.svg – Solomon Kullback and Richard Leibler introduce the Kullback–Leibler divergence
  • 1951 Green pog.svg – David A. Huffman invents Huffman encoding, a method of finding optimal prefix codes for lossless data compression
  • 1953 Green pog.svg – August Albert Sardinas and George W. Patterson devise the Sardinas–Patterson algorithm, a procedure to decide whether a given variable-length code is uniquely decodable
  • 1954 Purple pog.svg – Irving S. Reed and David E. Muller propose Reed–Muller codes
  • 1955 Purple pog.svg – Peter Elias introduces convolutional codes
  • 1957 Purple pog.svg – Eugene Prange first discusses cyclic codes
  • 1959 Purple pog.svg – Alexis Hocquenghem, and independently the next year Raj Chandra Bose and Dwijendra Kumar Ray-Chaudhuri, discover BCH codes
  • 1960 Purple pog.svg – Irving S. Reed and Gustave Solomon propose Reed–Solomon codes
  • 1962 Purple pog.svg – Robert G. Gallager proposes low-density parity-check codes; they are unused for 30 years due to technical limitations
  • 1965 Purple pog.svg – Dave Forney discusses concatenated codes
  • 1966 Green pog.svg – Fumitada Itakura (Nagoya University) and Shuzo Saito (Nippon Telegraph and Telephone) develop linear predictive coding (LPC), a form of speech coding[1]
  • 1967 Purple pog.svg – Andrew Viterbi reveals the Viterbi algorithm, making decoding of convolutional codes practicable
  • 1968 Purple pog.svg – Elwyn Berlekamp invents the Berlekamp–Massey algorithm; its application to decoding BCH and Reed–Solomon codes is pointed out by James L. Massey the following year
  • 1968 Red pog.svgChris Wallace and David M. Boulton publish the first of many papers on Minimum Message Length (MML) statistical and inductive inference
  • 1970 Purple pog.svg – Valerii Denisovich Goppa introduces Goppa codes
  • 1972 Purple pog.svg – Jørn Justesen proposes Justesen codes, an improvement of Reed–Solomon codes
  • 1972 Green pog.svg – Nasir Ahmed proposes the discrete cosine transform (DCT), which he develops with T. Natarajan and K. R. Rao in 1973;[2] the DCT later became the most widely used lossy compression algorithm, the basis for multimedia formats such as JPEG, MPEG and MP3
  • 1973 Red pog.svg – David Slepian and Jack Wolf discover and prove the Slepian–Wolf coding limits for distributed source coding[3]
  • 1976 Purple pog.svg – Gottfried Ungerboeck gives the first paper on trellis modulation; a more detailed exposition in 1982 leads to a raising of analogue modem POTS speeds from 9.6 kbit/s to 33.6 kbit/s
  • 1976 Green pog.svg – Richard Pasco and Jorma J. Rissanen develop effective arithmetic coding techniques
  • 1977 Green pog.svg – Abraham Lempel and Jacob Ziv develop Lempel–Ziv compression (LZ77)
  • 1982 Purple pog.svg – Valerii Denisovich Goppa introduces algebraic geometry codes
  • 1989 Green pog.svg – Phil Katz publishes the .zip format including DEFLATE (LZ77 + Huffman coding); later to become the most widely used archive container
  • 1993 Purple pog.svg – Claude Berrou, Alain Glavieux and Punya Thitimajshima introduce Turbo codes
  • 1994 Green pog.svg – Michael Burrows and David Wheeler publish the Burrows–Wheeler transform, later to find use in bzip2
  • 1995 Orange pog.svg – Benjamin Schumacher coins the term qubit and proves the quantum noiseless coding theorem
  • 2003 Purple pog.svg – David J. C. MacKay shows the connection between information theory, inference and machine learning in his book.
  • 2006 Green pog.svg – Jarosław Duda introduces first Asymmetric numeral systems entropy coding: since 2014 popular replacement of Huffman and arithmetic coding in compressors like Facebook Zstandard, Apple LZFSE, CRAM or JPEG XL
  • 2008 Purple pog.svg – Erdal Arıkan introduces polar codes, the first practical construction of codes that achieves capacity for a wide array of channels

References

  1. Gray, Robert M. (2010). "A History of Realtime Digital Speech on Packet Networks: Part II of Linear Predictive Coding and the Internet Protocol". Found. Trends Signal Process. 3 (4): 203–303. doi:10.1561/2000000036. ISSN 1932-8346. https://ee.stanford.edu/~gray/lpcip.pdf. 
  2. Nasir Ahmed. "How I Came Up With the Discrete Cosine Transform". Digital Signal Processing, Vol. 1, Iss. 1, 1991, pp. 4-5. https://www.scribd.com/doc/52879771/DCT-History. 
  3. Slepian, David S.; Wolf, Jack K. (July 1973). "Noiseless coding of correlated information sources". IEEE Transactions on Information Theory (IEEE) 19 (4): 471–480. doi:10.1109/TIT.1973.1055037. ISSN 0018-9448.