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Modeling Plant Form

Modeling Plant Form. Is plant form an emergent property of simple module systems?. L-Systems. L-systems are basically a way to rewrite something following a set of rules For instance: you have two letters a and b. The rules for rewriting are a->ab and b->a

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Modeling Plant Form

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  1. Modeling Plant Form Is plant form an emergent property of simple module systems?

  2. L-Systems • L-systems are basically a way to rewrite something following a set of rules • For instance: you have two letters a and b. • The rules for rewriting are a->ab and b->a • If we start with a b and start rewriting we get:

  3. The Turtle interpretation of strings • So we have a turtle with a string on its back, the turtle’s state is a triplet (x,y,α). This represents the turtle’s Cartesian coordinates and the angle (α) at which it is traveling. • Now, d = step size and ƒ =angle increment • So we can tell the turtle where to go if we give it directions. We will use the following symbols: • F = Move forward by one step length d • + = Turn counterclockwise by angle ƒ • - = Turn clockwise by angle ƒ

  4. Let’s put our turtle to work • Given the axiom w = F-F-F-F and the production successor p = F->F-F+FF-F-F+ • We can rewrite the phrase n times and tell out turtle to walk.

  5. Now let’s make it a little bit more complex • Edge rewriting productions substitute figures for polygon edges • Fl and Fr represent the turtle obeying the “move forward” command, but now Fl and Fr edges by lines forming left or right turns. • These curves can be space-filling and self avoiding (FASS).

  6. FASS curves generated from edge-rewriting L-systems

  7. Node rewriting substitutes polygons for nodes on the curve • Now we need more things: Entry and exit points (Pa and Qa) and an entry vector and an exit vector (pa and qa)

  8. You can also consider an array of m x m square tiles. • Each m x m contains a small box inside of it called a frame. Each frame bounds an open self-avoiding polygon. • Now when we connect many tiles we will get a macrotile

  9. 3-D

  10. Axial Trees • All of the previous examples were all a single line, but trees are not! • An axial tree starts from a base node • At each of its nodes there is at most one outgoing straight segment • All other edges are lateral segments • A terminal segment is an apex • An axis must: • The first segment in the sequence originates from the base or a lateral segment at a node • Each subsequent segment is straight • The last segment is not followed by any straight segment • So each axis is a mini axial tree! • An axis with all of its descendants is a branch

  11. Axes and branches are ordered as order 0 If they originated At the base and you Can guess the rest

  12. Let’s build a tree • We need to have a rewriting mechanism that acts on axial trees • Our rewriting rule, or tree production, must replace an edge with an axial tree

  13. Bracketed system

  14. Examples of bracketed system Note: The system for adding Leaves to this bush is Biologically whack

  15. Stochastic L-Systems • Since all plants don’t look the same we will add in some randomization.

  16. Context-sensitive L-Systems • We can make an L-System that show signal propagation so we can send signals from the leaves down or from the roots up. Plants Really Use Signals! Removing P2 makes Permanent signal

  17. Parametric L-Systems • Will help us show time, angles, and irrational line lengths (if d = 1, you cannot express sqrt(2). • Is easier than trying to add stuff to non-parametric model.

  18. Now for the real stuff…Let’s try to simulate herbaceous plants • Emphasis on space-time relation between plant parts • So there can be flowers and buds on the tree at the same time • Inherent capability of growth simulation • Our model is good for growing and we can simulate plants at different times and watch how they grow • Let’s only do herbaceous plants because: • The model assumes that the plant controls its own development (endogenous interaction). • Herbaceous plants have a lot of directions from their parents (lineage interaction). • Woody plants are much more sensitive to their environment, competition among branches and trees, and accidents (exogenous interaction).

  19. A glimpse at the models • http://algorithmicbotany.org/vmm-deluxe/QT/Greenash/apexview.qt • http://algorithmicbotany.org/vmm-deluxe/QT/Bluebell/field.qt • We can use confocal microscopes to get a real idea of how plants develop and then write a computer model that fits the behavior • We can also use empirical data on plant development • Other models try to use known mechanisms to explain the emergence of plant forms

  20. Three Main Type of Models • Partial L-Systems: Your basic model that is supposed to show us the possible structures of plants • L-System Schemata: Topology and temporal aspects of plants expressed, could help us understand mechanisms • Complete L-Systems: Geometric aspects added in (growth rates of internodes, values f branching angles, appearance of organs)

  21. Partial L-System

  22. Examples of cool things in L-system Schemata

  23. Examples of cool things in L-System Schemata

  24. Plants actually use signals and feedback loops a lot (WUS acts on SAM)! Examples of cool things in L-System Schemata • This says that the apex (a) produces internodes (I) and leaves (L) [p2]. The time in between growth is m [p1]. • After delay (d) a signal (s) [p3 an p4]. The signal is sent down the main axis with delay (u) steps per internode (I) [p5 and p7]. • [p6] removes the signal from the node by using an empty string (e) • When the signal reaches the apex (a), the a is transformed into a flowering state (A), which turns into a flower (K) [p8 and p9]. • Note: u<m or the signal is slower than growth!

  25. COMPLETE MODELS…MUAHAHA • These are good enough to make images • We can tell the model when to make branches using subapical growth • Plants actually grow like this!

  26. I like flowers! • There are a few different types of flowers we can make: • Monopoidal branching - lateral buds make flowers and can not make any more branches (raceme inflorescence)

  27. I still like flowers! • In sympodial branching the apex produces a flower bud (which cannot branch further) and two new lateral apices (cyme florescence).

  28. I hope you aren’t allergic to pollen • In polypodial branching, the apex makes three active apices, and at some point they change into buds (panicle inflorescence).

  29. Leaf model created trying to represent known biology (auxin), not bad right? -> But I want more! • Modeling exogenous effects are improving • http://algorithmicbotany.org/vmm-deluxe/QT/OpenLsys/two.qt • How leaves develop • How flowers develop • How roots develop A photosynthesis model ---> Clovers sense different wavelengths of light to perceive self-shade (light reflected off leaves is far-red) A model that makes branches fall off when The amount of energy leaves get from Photosynthesis isn’t enough to maintain Leaves and branch (self-thinning) --->

  30. Other models • Large trees don’t exhibit the recursive branching described in models because of exogenous factors. One group decided to model tree branching as a function of branch competition for space.

  31. By changing values for the number of attraction points, the kill distance, influence distance, and the distribution of attraction points…

  32. Resource Acquisition Model • Colasanti and Hunt wanted to see if their model could produce properties on different levels: • S-shaped growth curve for individuals • Equilibrium between shoots and roots • Plasticity in root and shoot foraging • Self thinning according to geometric power laws • Competitive exclusion • They used two binary trees • One for roots and one for shoots

  33. Wait…what’s a binary tree • Modules linked together. • Each module is linked to one parent module and potentially two offspring modules • A module “knows” the identity and state of its parent and offspring modules, but not the state of the whole plant • Base module has no parent and end module has no offspring • Spatial area made into cells, these cells can have resource units (light units for shoots/mineral nutrient units for roots) • The module can transport the units to base module • New growth requires a light unit and a mineral unit • They mutated the plant by giving it a competitive advantage for resources at the expense of extra energy

  34. Their Results • Success. • S-Shaped growth curve • Self-thinning • Plasticity in roots and shoots of modified plants • When resources are high, modified plants did well • When resources are low, regular plants did better • Could always make it better

  35. Conclusion • These models show that a very simple module behavior can account for many aspects of trees and herbaceous plants • By comparing these models to nature, we can learn more about the actual mechanisms in nature • Nature is math-y and pretty (or is math pretty and nature-y?) • Now when you see a tree, a bush, a leaf, a flower, or a root system…think about L-Systems and how cool nature is

  36. References • S. Wolfram, A New Kind of Science. Chapter 3, 6, 8.5, 8.6, 8.7 • P. Prusinkiewicz and A. Lindenmayer, The Algorithmic Beauty of Plants • R. L. Colassanti and R. Hunt, Resource Dynamics and Plant Growth: A Self-Assembling Model for Individuals • Runions et al., Modeling Trees with a Space Colonization Algorithm • Runions et al., Modeling and visualization of leaf venation patterns • O. Prusinkiewicz and Anne-Gaëlle Rolland-Lagan, Modeling plant morphogensis • P. Prusinkiewicz, Simulation Modeling of Plants and Plant Ecosystems

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