Abstract
The dichotomy between the qualitative and the quantitative has been a classic throughout the history of science. As will be seen, this dichotomy permeates all ontological levels of reality. In this work, phenomenological examples potentially related to semiosis are presented at the different levels established by Mario Bunge and Josep Ferrater Mora, contrasting the qualitative categorizations with the quantifiable physical reality. Likewise, the need to continue in the quantification of the biosemiotic and linguistic studies will be presented, while, in contrast, the need to establish a qualitative framework in the little-addressed study of technosemiotics will be raised, of potential interest given the notable advances that are expected in communication systems for inert artifacts in the next years. In short, in the thesis defended here the qualitative precedes the quantitative in the defining path of science.
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References
Altmann, E. G., & Gerlach, M. (2016). Statistical laws in linguistics. In Creativity and universality in language, 7–26. Cham: Springer.
Barbieri, M. (Ed.). (2007). Introduction to biosemiotics: The new biological synthesis. Dordrecht: Springer Science & Business Media.
Barceló, A. (2021). Larga vida a la economía crítica: el enfoque de la reproducción. Ediciones Asociación de Economía Crítica. Available in: http://www.asociacioneconomiacritica.org/larga-vida-a-la-economia-critica-el-enfoque-de-la-reproduccion/
Baronchelli, A., Loreto, V., & Puglisi, A. (2015). Individual biases, cultural evolution, and the statistical nature of language universals: The case of colour naming systems. PloS one,10(5), e0125019.
Bates, R. G. (1948). Definitions of pH Scales. Chemical reviews,42(1), 1–61.
Beloussov, L., Popp, F. A., Voeikov, V., & Van Wijk, R. (Eds.). (2000). Biophotonics and coherent systems. Moscow: Faculty of Biology, Lomonosov State University.
Bettencourt, L. M., Lobo, J., Helbing, D., Kühnert, C., & West, G. B. (2007). Growth, innovation, scaling, and the pace of life in cities. Proceedings of the National Academy of Sciences,104(17), 7301–7306.
Bischof, M., & Del Giudice, E. (2013). Communication and the emergence of collective behavior in living organisms: a quantum approach. Molecular biology international, 2013, ID:987549.
Blaxter, M. (2016). Imagining Sisyphus happy: DNA barcoding and the unnamed majority. Philosophical Transactions of the Royal Society B: Biological Sciences,371(1702), 20150329.
Bogaerts, L., Frost, R., & Christiansen, M. H. (2020). Integrating statistical learning into cognitive science. Journal of Memory and Language,115, 104167.
Brosché, M., & Strid, Å. (2003). Molecular events following perception of ultraviolet-B radiation by plants. Physiologia Plantarum,117(1), 1–10.
Brown, L. R., Gardner, G., & Halweil, B. (2014). Beyond Malthus: The Nineteen Dimensions of the Population Challenge. New York: Routledge.
Bunge, M. (1977). Treatise en Basic Philosophy III. Ontology I: the Furniture of the World. Dordrecht-Boston: Reidel.
Bunge, M. (1979). Treatise en Basic Philosophy IV. Ontology II: a World of Systems. Dordrecht-Boston: Reidel.
Bunge, M. (1983). Lingüística y filosofía. Barcelona: Ariel.
Bunge, M. (1998). Semiotic systems. In: Altmann & Koch (Eds.) Systems: new paradigms for the human sciences, 337–356. Berlin: De Gruyter.
Caetano-Anollés, G., Minhas, B. F., Aziz, F., Mughal, F., Shahzad, K., Tal, G., ... & Kim, K. M. (2017). The compressed vocabulary of the proteins of archaea. In Biocommunication of Archaea, 147–174. Cham: Springer.
Chandler, D. (2017). Semiotics: the basics. New York: Taylor & Francis.
Church, G. M., Gao, Y., & Kosuri, S. (2012). Next-generation digital information storage in DNA. Science,337(6102), 1628. https://doi.org/10.1126/science.1226355.
Colapietro, V. M. (1988). Peirce’s approach to the self: A semiotic perspective on human subjectivity. Suny Press.
Compagno, D. (Ed.). (2018). Quantitative semiotic analysis. Berlin: Springer.
Compagno, D., & Treleani, M. (2019). Introduction to Meaningful data/Données signifiantes. Semiotica,2019(230), 1–17.
Eco, U. (1979). A theory of semiotics. Bloomington Indiana: Indiana University Press.
Ekman, P. (1992). Are there basic emotions? Psychological Review,99(3), 550–553. https://doi.org/10.1037/0033-295X.99.3.550.
Ellis, E. C. (2019). Evolution: biodiversity in the Anthropocene. Current Biology,29(17), R831–R833.
Ellis, E. C. (2015). Ecology in an anthropogenic biosphere. Ecological Monographs,85(3), 287–331.
Emmeche, C. (2004). A-life, organism, and body: The semiotics of emergent levels. In M. Bedeau, P. Husbands, T. Hutton, S. Kumar, & S. Hideaki (Eds.), Workshop and Tutorial Proceedings: Ninth International Conference on the Simulation and Synthesis of Living Systems (Alife IX) (pp. 117–124). Boston:
Eroglu, S. (2014). Language-like behavior of protein length distribution in proteomes. Complexity,20(2), 12–21.
Faltýnek, D., & Lacková (2020). In the case of protosemiosis: Indexicality vs. iconicity of proteins. Biosemiotics, 1–18.
Favareau, D. (2010). Essential readings in biosemiotics. Anthology and commentary. Dordrecht: Springer.
Fernández, E. (2015). Evolution of signs, organisms and artifacts as phases of concrete generalization. Biosemiotics,8(1), 91–102.
Fernández, E. (2013). Semiosis and Control-from biosemiotics to technosemiotics and back. Thirteenth annual gathering in biosemiotics. Castiglioncello. Available at https://www.lindahall.org/services/reference/papers/fernandez/semiosis_and_control.pdf.
Ferrater Mora, J. (1979). De la materia a la razón. Madrid: Alianza.
Ferrater Mora, J. (2018). Escritos sobre ciencia. Pamplona: Editorial Laetoli.
Ferrer-i-Cancho, R., Forns, N., Hernández-Fernández, A., Bel-Enguix, G., & Baixeries, J. (2013). The challenges of statistical patterns of language: The case of Menzerath’s law in genomes. Complexity, 18(3), 11–17.
Gabaix, X. (1999). Zipf’s law for cities: an explanation. The Quarterly Journal of Economics,114(3), 739–767.
Goldstone, R. L., & Hendrickson, A. T. (2010). Categorical perception. Wiley Interdisciplinary Reviews: Cognitive Science,1(1), 69–78.
Grzybek, P. (2012). History of quantitative linguistics. Glottometrics,23, 70–80.
Guerrero, A. (2009). Inter and intraspecificity of chemical communication. Chemical Ecology,1, 415–437.
Gustison, M. L., Semple, S., Ferrer-i-Cancho, R., & Bergman, T. J. (2016). Gelada vocal sequences follow Menzerath’s linguistic law. Proceedings of the National Academy of Sciences,113(19), E2750–E2758.
Hardin, C. L., Hardin, C. L., & Maffi, L. (Eds.). (1997). Color categories in thought and language. Cambridge: Cambridge University Press.
Harnad, S. A. (Ed.). (1987). Categorical perception: The Groundwork of Cognition. Cambridge: Cambridge University Press.
Heesen, R., Hobaiter, C., Ferrer-i-Cancho, R., & Semple, S. (2019). Linguistic laws in chimpanzee gestural communication. Proceedings of the Royal Society B,286(1896), 20182900.
Hernández-Fernández, A., Baixeries, J., Forns, N., & Ferrer-i-Cancho, R. (2011). Size of the whole versus number of parts in genomes. Entropy,13(8), 1465–1480.
Hernández-Fernández, A. (2019). De Bunge a l’educació tecnològica al segle XXI, 145–177. In: Bunge, M. (2019). Filosofia de la tecnologia. Barcelona: Societat Catalana de Tecnologia, Institut d’ Estudis Catalans.
Hernández-Fernández, A., & Ferrer-i-Cancho, R. (2016). The infochemical core. Journal of Quantitative Linguistics,23(2), 133–153.
Hernández-Fernández, A., & Ferrer-i-Cancho, R. (2019). Lingüística cuantitativa. La estadística de las palabras. Barcelona: EMSE EDAPP / Prisanoticias.
Heuschele, J., & Candolin, U. (2007). An increase in pH boosts olfactory communication in sticklebacks. Biology Letters,3(4), 411–413.
Hoffmeyer, J. (2008). Biosemiotics: An examination into the signs of life and the life of signs. Scranton, PA: University of Scranton Press.
Joesaar, A., Yang, S., Bögels, B., van der Linden, A., Pieters, P., Kumar, B., Dalchau, N., Phillips, A., Mann, S., & de Greef, T. (2019). DNA-based communication in populations of synthetic protocells. Nature nanotechnology, 14(4), 369–378. https://doi.org/10.1038/s41565-019-0399-9.
Kaeslin, H. (2008). Digital integrated circuit design: from VLSI architectures to CMOS fabrication. Cambridge University Press.
Kellogg, C. E. (1993). Soil survey division staff: soil survey manual. Washington: United States Department of Agriculture.
Köhler, R., Altmann, G., & Piotrowski, R. G. (Eds.). (2008). Quantitative Linguistik/Quantitative Linguistics: Ein internationales Handbuch/An International Handbook (Vol. 27). Berlin: Walter de Gruyter.
Kull, K. (2016). The biosemiotic concept of the species. Biosemiotics,9, 61–71.
Leonhardt, S. D., Menzel, F., Nehring, V., & Schmitt, T. (2016). Ecology and evolution of communication in social insects. Cell,164(6), 1277–1287.
Li, W. (2012). Menzerath’s law at the gene-exon level in the human genome. Complexity,17(4), 49–53.
Lim, K. F. (2006). Negative pH does exist. Journal of chemical education,83(10), 1465.
Lundstrom, M. (2003). Moore’s law forever? Science,299(5604), 210–211.
Machado, I., & Romanini, V. (2012). Semiotics of Communication: From Semiosis of Nature to Culture. Biosemiotics,5(1), 47–60.
Malthus, T. R. (1798). An essay on the principle of population, as it affects the future improvement of society, with remarks on the speculations of Mr. Godwin, M. Condorcet, and other writers. London: J. Johnson’s in St. Paul’s Church-Yard.
Marakeby, H., Badr, E., Torkey, H., Song, Y., Monteil, C. L., Heath, L. S., et al. (2014). A system to automatically classify and name any individual genome-sequenced organism independently of current biological classification and nomenclature. PLoS One,9(2), e89142.
Mellouk, W., & Handouzi, W. (2020). Facial emotion recognition using deep learning: review and insights. Procedia Computer Science,175, 689–694.
Meyer, P. (2002). Laws and theories in quantitative linguistics. Glottometrics,5, 62–80.
Moore, G. (1965). Moore’s law. Electronics Magazine,38(8), 114.
Nieder, A. (2019). A brain for numbers: the biology of the number instinct. Cambridge: MIT press.
Noyce, R. N. (1977). Large-scale integration: What is yet to come? Science,195(4283), 1102–1106.
Peirce, C.S. (1894). What is a sign, in: Peirce, C. S. 1998. Charles S. Peirce: The Essential Writings. (Moore, Edward C., ed.) Amherst: Prometheus Books.
Queiroz, J., Emmeche, C., Kull, K., & El-Hani, C. (2011). The biosemiotic approach in biology: Theoretical bases and applied models. In R. Arp (Ed.), Terzis, G (pp. 91–130). Philosophical and scientific perspectives: Information and living systems.
Räty, M., & Huhta, V. (2003). Earthworms and pH affect communities of nematodes and enchytraeids in forest soil. Biology and Fertility of Soils,38(1), 52–58.
Roy, B. C., Frank, M. C., DeCamp, P., Miller, M., & Roy, D. (2015). Predicting the birth of a spoken word. Proceedings of the National Academy of Sciences,112(41), 12663–12668.
Saffran, J. R., Aslin, R. N., & Newport, E. L. (1996). Statistical learning by 8-month-old infants. Science,274(5294), 1926–1928.
Sandell, J. H., Gross, C. G., & Bornstein, M. H. (1979). Color categories in macaques. Journal of comparative and physiological psychology,93(4), 626–635.
Schatz, T., Feldman, N. H., Goldwater, S., Cao, X. N., & Dupoux, E. (2021). Early phonetic learning without phonetic categories: Insights from large-scale simulations on realistic input. Proceedings of the National Academy of Sciences,118(7),
Sebeok, T. A. (1965). Animal Communication: A communication network model for languages is applied to signaling behavior in animals. Science,147(3661), 1006–1014.
Shannon, C. E. (1948). A mathematical theory of communication. The Bell system technical journal,27(3), 379–423.
Shannon, C. E., & Weaver, W. (1949). The Mathematical Theory of Communication. Urbana: University of Illinois Press.
Sharov, A. A. (2010). Functional information: Towards synthesis of biosemiotics and cybernetics. Entropy,12(5), 1050–1070.
Sharov, A. A. (2018). Mind, agency, and biosemiotics. Journal of Cognitive science,19(2), 195–228.
Shahzad, K., Mittenthal, J. E., & Caetano-Anollés, G. (2015). The organization of domains in proteins obeys Menzerath-Altmann’s law of language. BMC systems biology,9(1), 1–13.
Schult, J., Preik, O., & Kirschner, S. (2020). The Importance of Biosemiotics for Morphology. Biosemiotics, 1–13.
Smil, V. (2019). Growth: from microorganisms to megacities. Cambridge, MA: Mit Press.
Smith, J.M. & Szathmary, E.,. (1997). The major transitions in evolution. Oxford: Oxford University Press.
Sun, Y., Ito, M., & Sezaki, K. (2019). Channel Capacity Analysis of Diffusive DNA based Molecular Communication. (2019). IEEE Wireless Communications and Networking Conference, doi: https://doi.org/10.1109/wcnc.2019.8885693.
Torre, I. G., Luque, B., Lacasa, L., Kello, C. T., & Hernández-Fernández, A., (2019). On the physical origin of linguistic laws and lognormality in speech. Royal Society open science,6(8), 191023.
Tsonis, A. A., Elsner, J. B., & Tsonis, P. A. (1997). Is DNA a language? Journal of theoretical Biology,184(1), 25–29.
Vaina, L. M., & Passingham, R. E. (Eds.). (2017). Computational Theories and Their Implementation in the Brain: The Legacy of David Marr. Oxford: Oxford University Press.
Valverde, S. (2016). Major transitions in information technology. Philosophical Transactions of the Royal Society B: Biological Sciences,371(1701), 20150450.
Von Uexküll, J. (1942). Meditaciones biológicas. La teoría de la significación. Madrid: Revista de Occidente.
Von Uexküll, J. (2010). A foray into the worlds of animals and humans: With a theory of meaning (Vol. 12). Minneapolis: Univ. of Minnesota Press. Translation of: Streifziige durch die Umwelten von Tieren und Menschen, 1934 Verlag von Julius Springer; and Bedeutungslehre, 1940 Verlag von J. A. Barth.
Waters, C.M. & Bassler, B.L. (2005). Quorum sensing: cell-to-cell communication in bacteria. Annual Review of Cell and Developmental Biology, 21, 319–46. PMID: 16212498. doi: https://doi.org/10.1146/annurev.cellbio.21.012704.131001.
Watson, S. K., Heesen, R., Hedwig, D., Robbins, M. M., & Townsend, S. W. (2020). An exploration of Menzerath’s law in wild mountain gorilla vocal sequences. Biology Letters,16(10), 20200380.
Wiener, N. (1948). Cybernetics or Control and Communication in the Animal and the Machine. Cambridge, MA: MIT press.
Wyatt, T. D. (2003). Pheromones and animal behaviour: communication by smell and taste. Cambridge: Cambridge University Press.
Zipf, G. K. (1949). Human behavior and the principle of least effort. Cambridge, MA: Addison-Wesley.
Acknowledgements
Thanks to Alfons Barceló and Ramon Ferrer-i-Cancho for the discussions that have largely led to the philosophical reflections contained here, and to L'udmila Lacková for her valuable comments on the draft of the article.
Funding
This work has been funded by the project PRO2021-S03 HERNANDEZ of Institut d’Estudis Catalans. AHF is also funded by the grant TIN2017-89244-R from Ministerio de Economía, Industria y Competitividad (Gobierno de España) and the recognition 2017 SGR-856 (MACDA) from AGAUR (Generalitat de Catalunya).
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Hernández-Fernández, A. Qualitative and Quantitative Examples of Natural and Artificial Phenomena. Biosemiotics 14, 377–390 (2021). https://doi.org/10.1007/s12304-021-09423-1
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DOI: https://doi.org/10.1007/s12304-021-09423-1