Functional Decomposition of Biological Systems Content adapted from: Nagel, J.K.S., Nagel, R.L.,...
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Transcript of Functional Decomposition of Biological Systems Content adapted from: Nagel, J.K.S., Nagel, R.L.,...
Functional Decomposition of Biological Systems
Content adapted from:Nagel, J.K.S., Nagel, R.L., Stone, R.B. & Mcadams, D.A., 2010. Function-based, biologically inspired concept generation. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 24, 521-535.
Today’s Journey
• DANE/Ask Nature facilitate searches for biological analogies
• Functional Modeling provides means to explore a problem while maintaining solution independence
• Today we talk about a larger process– Creating functional models of biological phenomena– Customer-Driven Bio-Inspired Design Process– Biology-Driven Bio-Inspired Design Process
Bio-Inspired Concept Generation Approaches
Last Lecture DANE/Ask Nature/Others
Biological System Functional Decomposition Process
1. Identify a suitable reference source for the system of interest (biology text book, etc.)
2. Learn about the biological system– Be the biologist– Use biological thesaurus to relate flows between
engineering systems and biology
3. Define the question– What is the functional model trying to answer?– This is a problem statement
4. Define the mimicry category
Biological System Functional Decomposition Process
5. Choose an organization level– Create the blackbox model– Read and investigate literature at this step
6. Develop functional model– Use thesaurus to translate functions– Biologists and engineers talk differently
7. Validate functional model
Engineering-to-Biology Thesaurus
• Most engineers are not biology domain experts
• Can lead to difficulty understanding biology descriptions
Mimicry Categories
• Physiology: the vital functions and activities of organisms, as opposed to their structure; the way in which a living organism or bodily part functions
• Morphology: the form and structure of an organism, and the associations among the structures of an organism
• Behavior: the sum of the responses of an organism to internal or external stimuli
• Strategy: generic behavior that is exhibited among multiple biological ranks to achieve different goals
Levels of Organization
• Biological systems contain many levels of organization– Organism, organ, tissue, cell, etc.
• Functional models at different levels of organization can provide different insights and inspiration– Where do you want to “focus” for inspiration?
Exercise
• What different levels of organization might be of interest in a shark and what might you expect to gain insight into for each?
• Consider each of the following levels: – atomic, molecular, molecular complexes, subcellular,
cellular, multicell systems, tissue, organ, multiorgan systems, organism, population, and behavior
10 minutes
Exercise
• What different levels of organization might be of interest in a shark and what might you expect to gain insight into for each?
• Here are some levels and insights:– Organism – Aerodynamics, energy
distribution/efficiency, motion in water, etc.– Organ – Gas exchange (gills), pumping (heart), etc.– Tissue – Low friction surface (skin)– Cell – Small scale motion, small scale assembly, etc.
Levels of Organization
• Since for any one organism or biological system there are many different levels of organization, each providing different insights, many different functional models are possible
• Choose the level that fits the application best
Case Study: Armadillo• Function of interest:
Defense (Stop Solid)• Level of Organization:
Organism• Note: Only flows and
functions relevant to the overall function of interest need to be included in the model
Case Study: Armadillo
Biological Functional Model
Exercise
• Come up with a functional model of the puffer fish defensive mechanism (swallowing water to make itself look bigger)
15 minutes
Exercise
• Come up with a functional model of the puffer fish defensive mechanism (swallowing water to make itself look bigger)
Biological Decomposition Uses
• Simplifying and translating biological system– Functional decomposition allows the abstraction
of a biological system with an interesting function– Once in functional form, the system can then be
relatively easily converted into an engineering system design
Biological Decomposition Uses
• Building a design repository database– Decomposing many biological systems and storing
the results in a searchable database allows for engineers to find biological inspiration for specific functions
– The OSU Design Engineering Lab Design Repository that includes both biological and mechanical systems
Design Repository
• OSU Design Repository– http://repository.designengineeringlab.org:8080/v
iew/browse.jsp