Information panspermia is the concept of life forms travelling across the universe by means of transmission of compressed information representing said life forms e.g. via genome coding, which can then enable the recovery of intelligent life.

Name

The concept was invented and coined by Vahe Gurzadyan,[1] and then listed by Stephen Webb as Solution 23 to the Fermi paradox: "The Armenian mathematical physicist Vahe Gurzadyan has posited an interesting hypothesis: we might inhabit a Galaxy 'full of traveling life streams'  strings of bits beamed throughout space."[2]

Background

Kolmogorov complexity is defined as the length of the computer program which enables the complete recovery of an object. Gurzadyan showed that the complexity of the human genome is relatively low due to non-random parts in the genomic sequences. Moreover, he noticed that since the genomic information on the terrestrial life, starting from bacteria up to humans, contains essential common parts, the entire terrestrial life information can be compressed and transmitted, as he estimated, to over Galactic distances via Arecibo-type antenna. Von Neumann automata networks or some other mechanism can perform the decoding of the information package. Within this concept, one can even assume that terrestrial life itself might be a result of such an information package.

Information panspermia has been discussed by Gurzadyan and Roger Penrose[3] within the scheme of Conformal Cyclic Cosmology, i.e. the possibility of transmission of information from pre-Big Bang aeon to ours via the cosmic microwave background radiation.[4][5]

Influence on strategy of analysis of intelligent signals

This concept assumes a different strategy of the study of the cosmic signals based on universal compressing and decoding principles.[6] Information panspermia is discussed in: [7]

"Gurzadyan’s idea offers a straightforward practical consequence: we should study alleged SETI signals from the point of view of the algorithmic information theory and we should try to identify and decode possible bit strings hidden in the noise."

References

  1. Gurzadyan, V.G. (2005). "Kolmogorov Complexity, String Information, Panspermia and the Fermi Paradox". Observatory. 125: 352–355. arXiv:physics/0508010. Bibcode:2005Obs...125..352G.
  2. Webb, Stephen (2015). If the Universe Is Teeming with Aliens... Where Is Everybody?. New York: Springer. ISBN 978-3319132358.
  3. Gurzadyan, V.G.; Penrose, R. (2016). "CCC and the Fermi paradox". European Physical Journal Plus. 131: 11. arXiv:1512.00554. Bibcode:2016EPJP..131...11G. doi:10.1140/epjp/i2016-16011-1. S2CID 73537479.
  4. Penrose, R. (2010). "Cycles of Time: An Extraordinary New View of the Universe". Bodley Head, London. Bibcode:2010cten.book.....P.
  5. Gurzadyan, V.G.; Penrose, R. (2013). "On CCC-predicted concentric low-variance circles in the CMB sky". European Physical Journal Plus. 128 (2): 22. arXiv:1302.5162. Bibcode:2013EPJP..128...22G. doi:10.1140/epjp/i2013-13022-4. S2CID 55249027.
  6. Gurzadyan, A. V.; Allahverdyan, A.E. (2016). "Non-random structures in universal compression and the Fermi paradox". European Physical Journal Plus. 131 (2): 26. arXiv:1603.00048. Bibcode:2016EPJP..131...26G. doi:10.1140/epjp/i2016-16026-6. S2CID 10666739.
  7. Ćirković, M. (2018). The Great Silence: Science and Philosophy of Fermi's Paradox. Oxford University Press. ISBN 978-0199646302.
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