METHODOLOGICAL APPROACHES OF DECISION TRANSFER FROM BIOLOGY TO ENGINEERING

The article provides an overview of existing methods of data transmission from biology to engineering. It is noted that all existing methods can be conditionally divided into two types: solution-based and problem-based. 

1. Fish, F. E. Passive and active flow control by swimming fishes and mammals / F. E. Fish, G.V. Lauder // Annual Review of Fluid Mechanics. – 2006. – V. 38. – P. 193–224.

2. Hydrodynamic flow control in marine mammals / F. E. Fish, L. E. Howle, M. M. Murray // Integrative and Comparative Biology. – 2008. – 211. – P. 1859–1867.

3. Watts, P. The influence of passive, leading edge tubercles on wing performance / P. Watts, F. Fish, // Proceedings of Twelfth International Symposium on Unmanned Untethered Submersible Technology (UUST), Durham, Autonomous Underwater Sea Institute, August 2001.

4. Ming, Z. Numerical Simulation of Flow Characteristics behind the Aerodynamic Performances on an Airfoil with Leading Edge Protuberances / Ming Zhao, Mingming Zhang, Jianzhong Xu //Engineering Applications of Computational Fluid Mechanics. – 2017. – V. 11. – PP. 193–209. – DOI:10.1080/19942060.2016.1277165.

5. Canter, N. Humpback whales inspire new wind turbine technology // Tribology & Lubrication Technology. – December, 2008. – P. 10–1.

6. Custodio, D Cavitation on hydrofoils with leading edge protuberances / Custodio D, Henoch C, Johari H. // Ocean Engineering. – 2018. – V. 162. – P. 196–208.

7. Britoa, T.O. Characterization of the Mandible Atta Laevigata and the Bioinspiration for the Development of a Biomimetic Surgical Clamp / T. O. Britoa [etc.] // Materials Research. – 2017. – 20 (6). – P. 1525–1533. – DOI: 10.1590/1980-5373-MR2016-1137.

8. Nachtigall, W. Vorbild Natur: Bionik¬Design für funktionelles Gestalten, 1997 (Springer, Berlin). – 176 p.

9. Speck, T. Die naturals innovationsquelle. In Technische Textilien / Speck, T. [etc.] // 2006, pp. 83–101 (Deutscher Fachverlag, Frankfurt, Germany).

10. Milwich, M. Biomimetics and technical textiles: solving engineering problems with the help of Nature’s wisdom / Milwich, M. [etc.] // Am. J. Botany. – 2006. – 93(10). – P. 1455–1465.

11. Вarthlott, W. and Neinhuis, C. The purity of sacred lotus or escape from contamination in biological surfaces. // Planta. – 1997. – 202. – 1–8.

12. Zerbst, E. Bionik: Biologische Funktionsprinzipien und ihre Anwendung. Teubner, Stuttgart, 1987. – 231 p.

13. Hill, B. Naturorientierte Loosungsfindung: Entwickeln und Konstruieren nach biologischen Vorbildern. Expert-Verlag, Renningen-Malmsheim, 1999. – P. 313–332.

14. Lindemann, U. Engineering design using biological principles / U. Lindemann & J. Gramann, // In: Proc. of the 8th International Design Conference DESIGN 2004, Dubrovnik, Croatia, 2004, 355–360 pp.

15. Cheong, H. Biologically meaningful keywords for functional terms of the functional basis / Cheong H, Chiu I, Shu L, Stone R. and McAdams D. // J. Mech. Des. 2011, Vol. 133. – p. 021007.

16. Baumeister, D. The Biomimicry Resource Handbook: A Seed Bank of Best Practices / Baumeister D, Tocke R, Dwyer J and Ritter S. // Biomimicry 3.8: Missoula. – 280 p.

17. Goel, A. K. Information-Processing Theories of Biologically Inspired Design / Goel A. K., Vattam S., Wiltgen B. and Helms M. // Biologically Inspired Design. – Berlin: Springer. 2014. – P. 127–152.

18. Vincent, J. et al. Biomimetics: Strategies for Product Design Inspired by Nature // A Mission to the Netherlands and Germany. – Report of A DTI Global Watch Mission, Pera, 2007.