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Wigner and friends, a map is not the territory! Contextuality in multi-agent paradoxes

Published 12 May 2023 in quant-ph | (2305.07792v4)

Abstract: Multi-agent scenarios, like Wigner's friend and Frauchiger-Renner scenarios, can show contradictory results when a non-classical formalism must deal with the knowledge between agents. Such paradoxes are described with multi-modal logic as violations of the structure in classical logic. Even if knowledge is treated in a relational way with the concept of trust, contradictory results can still be found in multi-agent scenarios. Contextuality deals with global inconsistencies in empirical models defined on measurement scenarios even when there is local consistency. In the present work, we take a step further to treat the scenarios in full relational language by using knowledge operators, thus showing that trust is equivalent to the Truth Axiom in these cases. A translation of measurement scenarios into multi-agent scenarios by using the topological semantics of multi-modal logic is constructed, demonstrating that logical contextuality can be understood as the violation of soundness by supposing mutual knowledge. To address the contradictions, assuming distributed knowledge is considered, which eliminates such violations but at the cost of lambda-dependence. We conclude by translating the main examples of multi-agent scenarios to their empirical model representation, contextuality is identified as the cause of their contradictory results.

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References (67)
  1. D. Frauchiger and R. Renner, Nature Communications 9, 3711 (2018).
  2. N. Nurgalieva and R. Renner, Contemporary Physics 61, 193 (2020).
  3. V. Vilasini, N. Nurgalieva, and L. del Rio, New Journal of Physics 21, 113028 (2019).
  4. E. P. Wigner, Remarks on the mind-body question, in Philosophical Reflections and Syntheses (Springer Berlin Heidelberg, Berlin, Heidelberg, 1995) pp. 247–260.
  5. D. Deutsch, International Journal of Theoretical Physics 24, 1 (1985).
  6. E. Schrödinger, Naturwissenschaften 23, 807 (1935).
  7. Č. Brukner, On the quantum measurement problem (2015), arXiv:1507.05255 [quant-ph] .
  8. Č. Brukner, Entropy 20, 350 (2018).
  9. E. G. Cavalcanti and H. M. Wiseman, Entropy 23, 925 (2021).
  10. M. Haddara and E. G. Cavalcanti, New Journal of Physics 25, 093028 (2023).
  11. A. Relaño, Phys. Rev. A 101, 032107 (2020).
  12. V. P. Rossi and D. O. Soares-Pinto, Phys. Rev. A 103, 052206 (2021).
  13. D. Schmid, Y. Yīng, and M. Leifer, A review and analysis of six extended wigner’s friend arguments (2023), arXiv:2308.16220 [quant-ph] .
  14. S. Kochen and E. P. Specker, The problem of hidden variables in quantum mechanics, in The Logico-Algebraic Approach to Quantum Mechanics: Volume I: Historical Evolution (Springer Netherlands, Dordrecht, 1975) pp. pp. 293–328.
  15. J. S. Bell, Physics Physique Fizika 1, 195 (1964).
  16. S. Abramsky and A. Brandenburger, New Journal of Physics 13, 113036 (2011a).
  17. S. Abramsky, S. Mansfield, and R. S. Barbosa, Electronic Proceedings in Theoretical Computer Science 95, 1–14 (2012).
  18. C. Okay and R. Raussendorf, Quantum 4, 217 (2020).
  19. S. B. Montanhano, Characterization of contextuality with semi-module Čech cohomology and its relation with cohomology of effect algebras (2021b), arXiv:2104.11411 [math.RA] .
  20. G. Birkhoff and J. V. Neumann, Annals of Mathematics 37, 823 (1936).
  21. A. M. Gleason, Journal of Mathematics and Mechanics 6, 885 (1957).
  22. A. Cabello, S. Severini, and A. Winter, Phys. Rev. Lett. 112, 040401 (2014).
  23. B. Amaral and M. T. Cunha, On geometrical aspects of the graph approach to contextuality (2017), arXiv:1709.04812 [quant-ph] .
  24. R. D. SORKIN, Modern Physics Letters A 09, 3119–3127 (1994).
  25. R. W. Spekkens, Phys. Rev. Lett. 101, 020401 (2008).
  26. S. B. Montanhano, Differential geometry of contextuality (2022), arXiv:2202.08719 [quant-ph] .
  27. A. Döring and M. Frembs, Contextuality and the fundamental theorems of quantum mechanics (2020), arXiv:1910.09591 [math-ph] .
  28. F. Shahandeh, Quantum computational advantage implies contextuality (2021), arXiv:2112.00024 [quant-ph] .
  29. S. Abramsky and A. Brandenburger, New Journal of Physics 13, 113036 (2011b).
  30. K. Beer and T. J. Osborne, Phys. Rev. A 98, 052124 (2018).
  31. A. Korzybski, Science and Sanity: An Introduction to Non-Aristotelian Systems and General Semantics, International non-Aristotelian library (International Non-Aristotelian Library Publishing Company, Brooklyn, NY, 1933) p. pp. 747–761.
  32. N. Nurgalieva and L. del Rio, Electronic Proceedings in Theoretical Computer Science 287, 267 (2019).
  33. P. T. Johnstone, Bulletin of the American Mathematical Society 8, 41 (1983).
  34. L. Wester, Electronic Proceedings in Theoretical Computer Science 266, 1–22 (2018).
  35. M. Lostaglio and J. Bowles, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 477, 10.1098/rspa.2021.0273 (2021).
  36. S. Abramsky, R. S. Barbosa, and S. Mansfield, Phys. Rev. Lett. 119, 050504 (2017).
  37. P. Janotta and H. Hinrichsen, Journal of Physics A: Mathematical and Theoretical 47, 323001 (2014).
  38. M. P. Müller, SciPost Phys. Lect. Notes , 28 (2021).
  39. J. H. Selby, C. M. Scandolo, and B. Coecke, Quantum 5, 445 (2021).
  40. S. Popescu and D. Rohrlich, Foundations of Physics 24, 379 (1994).
  41. F. Del Santo and N. Gisin, Phys. Rev. A 100, 062107 (2019).
  42. N. Gisin, Quantum Studies: Mathematics and Foundations 7, 197 (2019).
  43. N. Gisin, Synthese 199, 13345 (2021).
  44. S. Gogioso and N. Pinzani, Electronic Proceedings in Theoretical Computer Science 343, 301 (2021).
  45. S. Gogioso and N. Pinzani, The topology of causality (2023), arXiv:2303.07148 [quant-ph] .
  46. S. Abramsky, R. S. Barbosa, and A. Searle, Combining contextuality and causality: a game semantics approach (2023), arXiv:2307.04786 [quant-ph] .
  47. G. Masse, From the problem of future contingents to peres-mermin square experiments: An introductory review to contextuality (2021), arXiv:2105.13821 [quant-ph] .
  48. G. Leegwater, Foundations of Physics 52, 68 (2022).
  49. L. Walleghem and R. Wagner, Extended wigner’s friend paradoxes do not require nonlocal correlations (2023), arXiv:2310.06976 [quant-ph] .
  50. J. Lawrence, M. Markiewicz, and M. Żukowski, Quantum 7, 1015 (2023).
  51. S. Awodey and K. Kishida, The Review of Symbolic Logic 1, 146–166 (2008).
  52. D. Sustretov, Topological semantics and decidability (2007), arXiv:math/0703106 [math.LO] .
  53. J. C. C. McKinsey and A. Tarski, Annals of Mathematics 45, 141 (1944).
  54. J. M. Davoren, in Logical Foundations of Computer Science, edited by S. N. Artemov and A. Nerode (Springer Berlin Heidelberg, Berlin, Heidelberg, 2007) pp. pp. 162–179.
  55. M. Terra Cunha, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 377, 20190146 (2019).
  56. S. N. Filippov, T. Heinosaari, and L. Leppäjärvi, Phys. Rev. A 95, 032127 (2017).
  57. T. Heinosaari and M. M. Wolf, Journal of Mathematical Physics 51, 092201 (2010).
  58. S. Abramsky, in Categories for the Working Philosopher (Oxford University Press, 2017).
  59. P. T. Johnstone, Sketches of an elephant: a Topos theory compendium, Oxford logic guides (Oxford Univ. Press, New York, NY, 2002).
  60. E. Dzhafarov and J. Kujala, Entropy 20, 278 (2018).
  61. E. G. Cavalcanti, Phys. Rev. X 8, 021018 (2018).
  62. S. Abramsky, A. Brandenburger, and A. Savochkin, Electronic Proceedings in Theoretical Computer Science 171, 1–9 (2014).
  63. A. Brandenburger and N. Yanofsky, Journal of Physics A: Mathematical and Theoretical 41, 425302 (2008).
  64. J. S. Bell and A. Aspect, Speakable and Unspeakable in Quantum Mechanics: Collected Papers on Quantum Philosophy, 2nd ed. (Cambridge University Press, Cambridge, 2004).
  65. L. Hardy, Phys. Rev. Lett. 68, 2981 (1992).
  66. L. Hardy, Phys. Rev. Lett. 71, 1665 (1993).
  67. D. M. Greenberger, M. A. Horne, and A. Zeilinger, Going beyond bell’s theorem (2007), arXiv:0712.0921 [quant-ph] .
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