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Biologically Inspired Computation

Biologically Inspired Computation. Lecture 10: Ant Colony Optimisation. Swarm Algorithms. Inspiration from swarm intelligence has led to some highly successful optimisation algorithms. We will look at:

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Biologically Inspired Computation

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  1. Biologically Inspired Computation Lecture 10: Ant Colony Optimisation

  2. Swarm Algorithms Inspiration from swarm intelligence has led to some highly successful optimisation algorithms. We will look at: • Ant Colony (-based) Optimisation – a way to solve optimisation problems based on … well, you work it out! • Particle Swarm Optimisation — a different way to solve optimisation problems, based on the swarming behaviour of several kinds of organisms. This lecture is about Ant Colony Optimisation

  3. Ant Colony Optimization My starting point for these slides was some excellent ppt by Tony White(tony@sce.carleton.ca)

  4. Emergent Problem Solving in Lasius Niger ants, For Lasius Niger ants, [Franks, 89] observed: • regulation of nest temperature within 1 degree celsius range; • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. These are swarm behaviours – beyond what any individual can do.

  5. Explainable (arguably) as emergent property of many individuals operating simple rules? For Lasius Niger ants, [Franks, 89] observed: • regulation of nest temperature within 1 degree celsius range; • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. These are swarm behaviours – beyond what any individual can do.

  6. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. Solving an online/dynamic control problem

  7. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. A useful physical structure is built

  8. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. Exhibiting learning and memory

  9. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. Useful physical structure, plus online control

  10. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. Good housekeeping, better sanitation, etc …

  11. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. `Co-operation’ itself is maybe an emergent property. Plus, large items get relocated to a `better’ place.

  12. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. Emigration of colony is possibly emergent property environmental factors plus something like Reynold’s rules …

  13. What is the emergent property of the individual actions in each of these cases? • regulation of nest temperature • forming bridges; • raiding specific areas for food; • building and protecting nest; • sorting brood and food items; • cooperating in carrying large items; • emigration of a colony; • finding shortest route from nest to food source; • preferentially exploiting the richest food source available. SOLVING AN OPTIMISATION PROBLEM. How???

  14. A key player: Stigmergy Stigmergy is: indirect communication via interaction with the environment [Gassé, 59] • Sematectonic stigmergy • A problem gets solved bit by bit .. • Each individual does something based on the current state of the problem or task. • Individuals communicate with each other in the above way, affecting what each other does on the task. E.g. Many individuals sorting things into piles, as we did on Tuesday. • Sign-based stigmergy • Individuals leave markers or messages – these don’t solve the problem in themselves, but they affect other individuals in a way that helps them solve the problem … • E.g. as we will see, this is how ants find shortest paths.

  15. Ants Ants are behaviorally unsophisticated, but collectively they can perform complex tasks. Ants have highly developedsophisticatedsign-basedstigmergy • They communicate using pheromones; • They lay trails of pheromone that can be followed by other ants. • If an ant has a choice of two pheromone trails to follow, one to the NW, one to the NE, but the NW one is stronger – which one will it follow?

  16. Food source Nest Pheromone Trails Individual ants lay pheromone trails while travelling from the nest, to the nest or possibly in both directions. The pheromone trail gradually evaporates over time. But pheromone trail strength accumulate with multiple ants using path.

  17. E E 30 ants 30 ants D D D d=0.5 C C H C H B B B A A A Pheromone Trails continued E T = 1 T = 0 10 ants 20 ants 15 ants 15 ants d=1.0 H d=0.5 d=1.0 10 ants 20 ants 15 ants 15 ants 30 ants 30 ants

  18. Ants are agents that: Move along between nodes in a graph. They choose where to go based on pheromone strength (and maybe other things) An ant’s path represents a specific candidate solution. When an ant has finished a solution, pheromone is laid on its path, according to quality of solution. This affects behaviour of other ants by `stigmergy’ … Ant Colony Optimisation Algoirithms: Basic Ideas

  19. E.g. A 4-city TSP Initially, random levels of pheromone are scattered on the edges A B D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  20. E.g. A 4-city TSP An ant is placed at a random node A B D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  21. E.g. A 4-city TSP The ant decides where to go from that node, based on probabilities calculated from: - pheromone strengths, - next-hop distances. Suppose this one chooses BC A B D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  22. E.g. A 4-city TSP The ant is now at AC, and has a `tour memory’ = {B, C} – so he cannot visit B or C again. Again, he decides next hop (from those allowed) based on pheromone strength and distance; suppose he chooses CD A B D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  23. E.g. A 4-city TSP The ant is now at D, and has a `tour memory’ = {B, C, D} There is only one place he can go now: A B D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  24. E.g. A 4-city TSP So, he finished his tour, having gone over the links: BC, CD, and DA. AB is added to complete the tour. A B Now, pheromone on the tour is increased, in line with the fitness of that tour. D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  25. E.g. A 4-city TSP A B Next, pheromone everywhere is decreased a little, to model decay of trail strength over time D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  26. E.g. A 4-city TSP We start again, with another ant in a random position. B Where will he go? Next time, the actual algorithm and variants. D C Pheromone AB: 10, AC: 10, AD, 30, BC, 40, CD 20 Ant

  27. We have a TSP, with n cities. 1. We place some ants at each city. Each ant then does this: It makes a complete tour of the cities, coming back to its starting city, using a transition rule to decide which links to follow. By this rule, it chooses each next-city at random, but biased partly by the pheromone levels existing at each path, and biased partly by heuristic information. 2. When all ants have completed their tours. Global Pheromone Updating occurs. The current pheromone levels on all links are reduced (I.e. pheromone levels decay over time). Pheromone is lain (belatedly) by each ant as follows: it places pheromone on all links of its tour, with strength depending on how good the tour was. Then we go back to 1 and repeat the whole process many times, until we reach a termination criterion. The ACO algorithm for the TSP[a simplified version with all essential details]

  28. The transition rule T(r,s) is the amount of pheromone currently on the path that goes directly from city r to city s. H(r,s) is the heuristic value of this link – in the classic TSP application, this is chosen to be 1/distance(r,s) -- I.e. the shorter the distance, the higher the heuristic value. is the probability that ant k will choose the link that goes from r to s is a parameter that we can call the heuristic strength The rule is: Where our ant is at city r, and s is a city as yet unvisited on its tour, and the summation is over all of k’s unvisited cities

  29. Global pheromone update Ak(r,s) is the amount of pheromone added to the (r, s) link by ant k. m is the number of ants is a parameter called the pheromone decay rate. and Lk is the length of the tour completed by ant k T(r, s) at the next iteration becomes: Where Study these – they’re not that hard. How do you think the parameters m, beta, rho etc … affect the search?

  30. We’ll see more about Ants in two lectures from now. Meanwhile see here if you’re very interested in it: • http://iridia.ulb.ac.be/dorigo/ACO/ACO.html Next week, particle swarm optimisation, and then a lecture about advanced and applied versions of both PSO and ACO. But let’s see an applet

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