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Modeling Adaptive Robot Swarms

Learn about tools & models to study adaptive robot swarms, effects of individual characteristics, system size on performance, and optimization techniques for improved collective behavior. Understand why analyzing such systems is important and how adaptation and memory play crucial roles in robotic swarm operations.

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Modeling Adaptive Robot Swarms

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  1. Modeling Adaptive Robot Swarms Not an Inverse Problem Kristina Lerman Aram Galstyan USC Information Sciences Institute

  2. Why Analyze Adaptive Systems? • To predict • Behavior of the system under new conditions • Aspects of the system not studied experimentally • Large numbers of robots • Dynamic environments • To control • Find parameters that optimize system performance • Optimal number of robots for the task • Find parameters that prevent instabilities, etc. • To understand • How individual robot characteristics affect collective behavior • How system size affects performance of the system Modeling Adaptive Robot Swarms

  3. Modeling and Analysis Tools • Microscopic (discrete) models describe/model individual robot’s behavior • Equations of motion approach • Explicitly account for all interactions • Solve to obtain trajectories • E.g., pheromone-based trail formation (Schweitzer et al., 1997) • Microscopic simulations Abstract individual robot properties • Probabilistic models (Martinoli et al., 1999) • Robot’s actions modeled as series of stochastic events • E.g., collaboration in robots (Ijspert et al., 2001) • Others: cellular automata, molecular dynamics, etc. Modeling Adaptive Robot Swarms

  4. Modeling and Analysis Tools (cont) • Macroscopic (continuous) models describe collective behavior of groups of robots • Finite difference equations • Collaboration in robots (Martinoli & Easton, 2003) • Synchronous • Rate Equations • Continuous limit of finite difference equations • Alternatively, derived from Stochastic Master Equation • Collaboration (Lerman et al., 2001) and foraging (Lerman & Galstyan, 2002) in robots • Asynchronous Modeling Adaptive Robot Swarms

  5. Rate Equations • We will use macroscopic models – Rate Equations – to study robots • More computationally efficient than microscopic models • Directly describe experimental observations • Rate Equations describe average collective behavior, not a specific experiment • describe results averaged over many experiments • They are usually phenomenological • Not derived from first principles • Are easier to construct because you don’t have to explicitly model many individual details • Microscopic details appear only in parameters of models • Can be derived from stochastic microscopic description Modeling Adaptive Robot Swarms

  6. What We Can Model Now • Types of robots modeled • Reactive robots • Perception and action are tightly coupled • No memory or use of historical information • Can use timers to trigger actions • Adaptive robots • Change their behavior in response to environmental changes or actions of other robots • These are simple robots • No intentionality • No abstract representations • Distributed system • collective behavior arises out of local interactions among robots Modeling Adaptive Robot Swarms

  7. Why Amenable to Analysis Individual robots can be modeled as stochastic processes Individual robot’s behavior subject to • External forces • may not be anticipated • Noise • fluctuations and random events • Other robots with complex trajectories • Can’t predict which robots will interact • Errors in sensors and actuators • Randomness programmed into controllers • e.g., avoidance Modeling Adaptive Robot Swarms

  8. Our Results • A framework for modeling collective behavior in reactive and adaptive robot systems • Derived equations from theory of stochastic processes • “Recipe” for creating application-specific models from individual robot controllers • Models of distributed robot systems • Collaborative stick-pulling • Qualitative agreement with experimental/simulations results • Analytic form for critical parameters • Foraging • Quantitative agreement with simulations results • Optimal group size and its dependence on individual robot parameter • Dynamic task allocation • Individual robot transition rules for stable steady state distribution Modeling Adaptive Robot Swarms

  9. Adaptation in Robot Swarms Adaptation is crucial for robotic swarms functioning in unstructured dynamic environments Adaptation allows robots • to change their behavior in response to environmental changes or actions of other robots • to improve the overall performance of the system Modeling Adaptive Robot Swarms

  10. Memory as a Mechanism for Adaptation Memory-based adaptation • Robot makes observations; stores them in memory • Uses observations to estimate the state of the environment and other robots • Modifies its behavior accordingly Adaptive robots using memory of length m to make decisions about future actions can be represented as a generalized Markov process of order m Modeling Adaptive Robot Swarms

  11. Adaptive Robots as Markov Processes • Individual robot probability distribution • p(n,t) = probability robot is in state n at time t • Generalized Markov property: robot’s state at time t+Dt depends on its state at time t, and history of past m-1 states • h={(n1,t), (n2,t-Dt),…, (nm,t-(m-1)Dt)} • Change in probability density Modeling Adaptive Robot Swarms

  12. Master Equation for Adaptive Systems • In the continuum limit, with transition rates Similar to the Stochastic Master Equation that describes evolution of physical systems Modeling Adaptive Robot Swarms

  13. From One to Many • Collective robot state If robots are independent and indistinguishable • Collective configuration described by n={N1,…, NL} • Nj = number of robots in state j • P(n,t) = probability system is in configuration n at t • Master Equation for P(n,t) specifies how the entire system evolves in time • However, ME is often difficult to formulate and solve – it is difficult to define correct probability distribution for a system Modeling Adaptive Robot Swarms

  14. Rate Equation Instead, we work with the Rate Equation • Derived from the Master Equation • “First moment” of the ME • Describes how the average number of robots in state k changes in time where <…>h denotes average over histories • No need to know exact probability distributions • Used in Ecology, Population Dynamics Modeling Adaptive Robot Swarms

  15. Dynamic Task Allocation • Task Robots are allocated to collect red or green pucks • Goal Dynamically achieve an appropriate division of labor • Mechanism • Robot makes local observations and adds them to memory • Each robot estimates the proportion of pucks and robots in the environment (from memory), and switches state accordingly Jones & Mataric Modeling Adaptive Robot Swarms

  16. Modeling Adaptive Task Allocation • NR|G(t) number of robots in Red|Green state • MR|G(t) number of Red|Green tasks • aR|G(t,h)rate robots switch to Red|Green state • bR|G rate robots complete Red|Green tasks • mR|G rate at which new Red|Green tasks are added Modeling Adaptive Robot Swarms

  17. Transition Rates • Transition rates depend on nR,obs=NR,obs/(NR,obs+NG,obs): observed density of Red robots mR,obs= MR,obs/(MR,obs+MG,obs): observed density of Red pucks • Mathematical form of transition rates • Steady-state (SS): • dnR/dt=0=aR nG-aGnR • Desired SS solution: nR,SS= mR • Intuitive guess: aR=f(nR-mR) • Will lead to desired SS solution only when f(nR-mR)=0 • Informed by analysis: aR=(1- mR)f(nR-mR) • guarantees desired steady-state is satisfied non-trivially Modeling Adaptive Robot Swarms

  18. Mathematical Form for f Modeling Adaptive Robot Swarms

  19. Intuitive vs Informed Transition Rates Simulations results with different transition rates Intuitive (power f ): aR=f(nR-mR) Informed (power f ): aR=(1- mR)f(nR-mR) time Courtesy of C. Jones Modeling Adaptive Robot Swarms

  20. … … … All robots History and Transition Rates t t-D … t-|h|D Robot’s memory Modeling Adaptive Robot Swarms

  21. Time Delay Equations • Initial conditions Modeling Adaptive Robot Swarms

  22. Dynamics of Red Robots Linear f • Solutions show oscillations characteristic of delay equations • Solutions eventually relax to puck distribution • Magnitude of oscillations and relaxation time depend on size of history window Modeling Adaptive Robot Swarms

  23. Solutions for Different f Same h Modeling Adaptive Robot Swarms

  24. Jones & Mataric

  25. Conclusions • Created a model of collective dynamics based on theory of stochastic processes • Reactive robots • Adaptive robots • Applied formalism to distributed robotic systems • Collaborative stick-pulling • Foraging • Dynamic task allocation • Results • Theoretical predictions agree at least qualitatively with results of experiments and simulations • Analytic results not obtainable by other methods • Insights into robot design (form for transition rates) Modeling Adaptive Robot Swarms

  26. Future Work • Beyond the Rate Equation • Take into account fluctuations • Noisy observations • Formulate and solve the collective Master Equation • Appropriate form for probability distribution function for dynamic task allocation application • More realistic models • Don’t coarse-grain behaviors • Automatic model construction • Other systems – new challenges • Self-reconfigurable robots • Nano-robots Modeling Adaptive Robot Swarms

  27. Roadmap to Theory • Starting with an individual robot • Derive stochastic Master Equation • ME describes how robot’s state changes in time • State=action or behavior the robot is executing • Make transition to a multi-robot system • Derive collective Master Equation describes how configuration of the system evolves in time • ME is often difficult to formulate and solve • Instead, work with the Rate Equation • “Mean” or “First Moment” of the ME • Practical “recipe” for constructing the Rate Equation from individual robot controller Modeling Adaptive Robot Swarms

  28. start searching Puck detected Reach home homing pickup Gripper closed Representation of Reactive Robots • Finite state automata used to represent individual reactive robots (Arbib et al., 1981) • State = behavior; transitions between states • Example: simplified foraging diagram • Collective behavior is captured by the same FSA • Each robot in exactly one of finite number of states • State = number of robots executing that behavior Modeling Adaptive Robot Swarms

  29. search Avoid obstacle Avoid obstacle Detect object search search Coarse-graining • Coarse-graining reduces the complexity of the model • Helps construct a minimal model that explains experiments Modeling Adaptive Robot Swarms

  30. start searching homing pickup A “Recipe” for Rate Equations Initial conditions: Ns(t=0)=N, Nh(0)=0, Np(0)=0 Modeling Adaptive Robot Swarms

  31. Transition Rates • Transition is triggered • By a stimulus • Obstacle, another robot in a particular state, location (e.g., home) • By a timer • Turn in a random direction for x seconds • Calculating transition rates • Calculated under assumptions • Triggers are uniformly distributed in space • Robots encounter triggers randomly • Estimated from data by • Calibration • Run experiment or simulation for a single robot in an arbitrarily complex environment and measure relevant parameters • Fitting • Fit the model to the data Modeling Adaptive Robot Swarms

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