Plans and Planning in Mathematical Proofs

Hamami, Yacin; Morris, Rebecca L.E.A.

doi:10.1017/S1755020319000601

Request a copy

Article (Scientific journals)

Plans and Planning in Mathematical Proofs

Hamami, Yacin; Morris, Rebecca L.E.A.

2021 • In Review of Symbolic Logic, 14 (4), p. 1030 - 1065

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/290264

DOI
10.1017/S1755020319000601

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Plans_and_Planning_in_Mathematical_Proofs.pdf

Author postprint (623.89 kB)

Request a copy

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Mathematical practice; Mathematical proof; Planning agency; Proof plan; Mathematics (miscellaneous); Philosophy; Logic

Abstract :

[en] In practice, mathematical proofs are most often the result of careful planning by the agents who produced them. As a consequence, each mathematical proof inherits a plan in virtue of the way it is produced, a plan which underlies its “architecture” or “unity.” This paper provides an account of plans and planning in the context of mathematical proofs. The approach adopted here consists in looking for these notions not in mathematical proofs themselves, but in the agents who produced them. The starting point is to recognize that to each mathematical proof corresponds a proof activity which consists of a sequence of deductive inferences—i.e., a sequence of epistemic actions—and that any written mathematical proof is only a report of its corresponding proof activity. The main idea to be developed is that the plan of a mathematical proof is to be conceived and analyzed as the plan of the agent(s) who carried out the corresponding proof activity. The core of the paper is thus devoted to the development of an account of plans and planning in the context of proof activities. The account is based on the theory of planning agency developed by Michael Bratman in the philosophy of action. It is fleshed out by providing an analysis of the notions of intention—the elementary components of plans—and practical reasoning—the process by which plans are constructed—in the context of proof activities. These two notions are then used to offer a precise characterization of the desired notion of plan for proof activities. A fruitful connection can then be established between the resulting framework and the recent theme of modularity in mathematics introduced by Jeremy Avigad. This connection is exploited to yield the concept of modular presentations of mathematical proofs which has direct implications for how to write and present mathematical proofs so as to deliver various epistemic benefits. The account is finally compared to the technique of proof planning developed by Alan Bundy and colleagues in the field of automated theorem proving. The paper concludes with some remarks on how the framework can be used to provide an analysis of understanding and explanation in the context of mathematical proofs.

Disciplines :

Philosophy & ethics

Author, co-author :

Hamami, Yacin ; Université de Liège - ULiège > Traverses ; Centre for Logic and Philosophy of Science, Vrije Universiteit Brussel, Belgium ; CENTRE FOR LOGIC AND PHILOSOPHY OF SCIENCE, VRIJE UNIVERSITEIT BRUSSEL, B-1050, BRUSSELS, Belgium

Morris, Rebecca L.E.A.

Language :

English

Title :

Plans and Planning in Mathematical Proofs

Publication date :

29 December 2021

Journal title :

Review of Symbolic Logic

ISSN :

1755-0203

eISSN :

1755-0211

Publisher :

Cambridge University Press

Volume :

Issue :

Pages :

1030 - 1065

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S1755020319000601

Available on ORBi :

since 04 May 2022

Statistics

Number of views

23 (0 by ULiège)

Number of downloads

0 (0 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Avigad, J. (2006). Mathematical method and proof. Synthese, 153(1), 105–159.
———. (2020). Modularity in mathematics. The Review of Symbolic Logic, 13(1), 47–79.
Avigad, J. & Morris, R. L. (2016). Character and object. The Review of Symbolic Logic, 9(3), 480–510.
Bedford, E. & Smillie, J. (1998). Polynomial diffeomorphisms of C2: VI. Connectivity of J. Annals of Mathematics, Second Series, 148(2), 695–735.
Boghossian, P. (2014). What is inference? Philosophical Studies, 169(1), 1–18.
Bratman, M. E. (1987). Intention, Plans, and Practical Reason. Cambridge, MA: Harvard University Press. Reissued by CSLI Publications, Stanford, CA, 1999 (citations are to the latter edition).
———. (2014). Shared Agency: A Planning Theory of Acting Together. New York: Oxford University Press.
Bundy, A. (1988). The use of explicit plans to guide inductive proofs. In Lusk, E. and Overbeek, R., editors. 9th International Conference on Automated Deduction. Lecture Notes in Computer Science, Vol. 310. Berlin: Springer-Verlag, pp. 111–120.
Bundy, A. (1991). A science of reasoning. In Lassez, J.-L. and Plotkin, G., editors. Computational Logic: Essays in Honor of Alan Robinson. Cambridge, MA: MIT Press, pp. 178–198.
Bundy, A(1996). Proof planning. In Drabble, B., editor. Proceedings of the Third International Conference on Artificial Intelligence Planning Systems. Menlo Park, CA, pp. 261–267.
Bundy,A., Basin,D., Hutter,D.,& Ireland,A.(2005).Rippling:Meta-LevelGuidance for Mathematical Reasoning. Cambridge Tracts in Theoretical Computer Science, Vol. 56. Cambridge: Cambridge University Press.
Bundy, A., van Harmelen, F., Horn, C., & Smaill, A. (1990). The OYSTER-CLAM system. In Stickel, M. E., editor. 10th International Conference on Automated Deduction. Lecture Notes in Artificial Intelligence, Vol. 449. Berlin: Springer-Verlag, pp. 647–648.
Chemla, K. & Virbel, J. (2015). Texts, Textual Acts and the History of Science. Cham: Springer.
Corcoran, J. (1989). Argumentations and logic. Argumentation, 3(1), 17–43.
Dixon, L. & Fleuriot, J. (2003). Isa Planner: A prototype proof planner in Isabelle. In Baader, F., editor. Automated Deduction–CADE-19. Lecture Notes in Computer Science, Vol. 2741. Berlin: Springer-Verlag, CADE, pp. 279–283.
Faber, C. & Pandharipande, R. (2003). Hodge integrals, partition matrices, and the λg conjecture. Annals of Mathematics, Second Series, 157(1), 97–124.
Feferman, S. (2012). And so on...: Reasoning with infinite diagrams. Synthese, 186(1), 371–386.
Folina, J. (2018). Towards a better understanding of mathematical understanding. In Piazza, M. and Pulcini, G., editors. Truth, Existence and Explanation. Cham: Springer, pp. 121–146.
Fraleigh, J. B. (2003). A First Course in Abstract Algebra (seventh edition). London: Pearson Education.
Ganesalingam, M. & Gowers, T. (2017). A fully automatic theorem prover with human-style output. Journal of Automated Reasoning, 58(2), 253–291.
Gowers, T. (2002). Mathematics: A Very Short Introduction. Oxford: Oxford University Press.
Hamami, Y. (2018). Mathematical inference and logical inference. The Review of Symbolic Logic, 11(4), 665–704.
———. (2019). Mathematical rigor and proof. The Review of Symbolic Logic. To appear.
Hardy, G. H., Littlewood, J. E., & Pólya, G. (1934). Inequalities. Cambridge: Cambridge University Press.
Haylock, D. & Cockburn, A. (2008). Understanding Mathematics for Young Children: A Guide for Foundation Stage and Lower Primary Teachers. London: SAGE Publications Ltd.
Ireland, A. (1992). The use of planning critics in mechanizing inductive proofs. In Voronkov, A., editor. International Conference on Logic for Programming Artificial Intelligence and Reasoning. Lecture Notes in Computer Science, Vol. 624. Berlin: Springer-Verlag, pp. 178–189.
Ireland, A. & Bundy, A. (1996). Productive use of failure in inductive proof. Journal of Automated Reasoning, 16(1–2), 79–111.
Lamport, L. (1995). How to write a proof. The American Mathematical Monthly, 102(7), 600–608.
Lamport, L.. (2012). How to write a 21st century proof. Journal of Fixed Point Theory and Applications, 11(1), 43–63.
Leron, U. (1983). Structuring mathematical proofs. The American Mathematical Monthly, 90(3), 174–185.
Michener, E. R. (1978). Understanding understanding mathematics. Cognitive Science, 2(4), 361–383.
Milner, R. (1972). Logic for computable functions: Description of a machine implementation. Technical Report STAN-CS-72-288, A.I. Memo 169, Stanford University.
Morris, R. L. (2020). Motivated proofs: What they are, why they matter and how to write them. The Review of Symbolic Logic, 13(1), 23–46.
Poincaré, H. (1900/1996). Intuition and logic in mathematics. In Ewald, W., editor. From Kant to Hilbert: A Source Book in the Foundations of Mathematics (Volumes I and II), Vol. 19. Oxford: Clarendon Press, pp. 1012–1020.
Poincaré, H.. (1908). Science et Méthode. Paris: Ernest Flammarion. Translated to English by Francis Maitland as Science and Method. London: Thomas Nelson & Sons, 1914. (Citations are to translation.)
Pólya, G. (1945). How to Solve It: A New Aspect of Mathematical Method. Princeton, NJ: Princeton University Press.
Pólya, G. (1949). With, or without, motivation. The American Mathematical Monthly, 56(10), 684–691.
Pólya, G(1954a). Mathematics and Plausible Reasoning: Induction and Analogy in Mathematics, Vol. 1. Princeton, NJ: Princeton University Press.
Pólya, G(1954b). Mathematics and Plausible Reasoning: Patterns of Plausible Inference, Vol. 2. Princeton, NJ: Princeton University Press.
Pólya, G(1962). Mathematical Discovery: On Understanding, Learning, and Teaching Problem Solving (Two Volumes). New York: John Wiley & Sons, Inc.
Prawitz, D. (2012). The epistemic significance of valid inference. Synthese, 187(3), 887–898.
Prawitz, D. (2015). Explaining deductive inference. In Wansing, H., editor. Dag Prawitz on Proofs and Meaning. Cham: Springer, pp. 65–100.
Rav, Y. (1999). Why do we prove theorems? Philosophia Mathematica, 7(3), 5–41.
Robinson, J. A. (2000). Proof = guarantee + explanation. In Hölldobler, S., editor. Intellectics and Computational Logic. Applied Logic Series, Vol. 19. Dordrecht: Kluwer Academic Publishers, pp. 277–294.
Scott, D. S. (1993). A type-theoretical alternative to ISWIM, CUCH, OWHY. Theoretical Computer Science, 121(1–2), 411–440.
Steele, J. M. (2004). The Cauchy-Schwarz Master Class: An Introduction to the Art of Mathematical Inequalities. Cambridge: Cambridge University Press.
Sundholm, G. (2012). “Inference versus consequence” revisited: Inference, consequence, conditional, implication. Synthese, 187(3), 943–956.
Tanswell, F. (2019). Go forth and multiply! On actions, instructions and imperatives in mathematical proofs. Unpublished manuscript.
van Benthem, J. (2018). Constructive agents. Indagationes Mathematicae, 29(1), 23–35.
Wright, C. (2014). Comment on Paul Boghossian, “What is inference”. Philosophical Studies, 169(1), 27–37.