1 / 46

AMAM Conference 2005

AMAM Conference 2005. Adaptive Motion in Animals and Machines. Outline of the talk. Short AMAM conference overview Introduction to Embodied Artificial Intelligence (keynotes, R. Pfeifer) More detailed look at: Sensory Motor Coordination Value-Systems. AMAM: Conference Overview.

hanne
Download Presentation

AMAM Conference 2005

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. AMAM Conference 2005 Adaptive Motion in Animals and Machines

  2. Outline of the talk • Short AMAM conference overview • Introduction to Embodied Artificial Intelligence (keynotes, R. Pfeifer) • More detailed look at: • Sensory Motor Coordination • Value-Systems

  3. AMAM: Conference Overview • Motivation of studying Biology • Source of inspiration for robotics • Model features of rather simple animals (insects…) • Robots and animals have to solve the same physical problems • Robots are useful tools for computational neuroscience • Testing Neural Models within a complete sensing-acting loop

  4. Biorobotics • Bio-inspired technologies • New sensors: Whiskers and Antennas • Muscle-Like (flexible) actuators • Flexible robotic arms and hands • Biped and humanoid robots • Numerical Models of animal and human locomotion • Central Pattern Generator based and other control methods • Some robots for illustratoin:

  5. AMAM: robots • Scorpion [Kirchner05] • 8 legged robot • BigDog [Buehler, Boston Dynamics]

  6. AMAM: Robots • Fish Robot • Iida • Stumpy • „Special“ robot to investigate cheap design locomotion (Iida)

  7. AMAM Conference: Robots • ZAR 4 [boblan05] • Bionic robot arm driven by artificial muscels • And many more: • Insects : • Coackroaches[ritzmann05] • Worm [menciassi05] • Amoebic Robots [ishiguro05] • Bisam Rat [albiez05]

  8. Embodied Artificial Intelligence[Pfeifer99, Iida03] • Not interested in the control aspects of robots alone, but rather in designing entire systems • Morphology, Materials + Control • Synthetic Methology: Understanding intelligent behavior by building • Concentrate on complete autonomous robots • Self-Sufficient: Sustain itself over a extended period of time • Situatedness: acquires all information about the environment from its own sensory system • „Lives“ in a specified ecological niche: no need for universal robots • Embodiment: real physical agents • Adaptivity • „Why do plants have no brain? They do not move.“ [Brooks] • Often aspects of only simple animals are modeled by robots (locomotion of insects…) • It took evolution 3 billion years to evolve insects/legged locomotion, but only 500 million more years to develop humans • => locomotion must be a hard problem

  9. Embodied AI: Principles • Emergence: • Emergent Behaviours: „emerge“ by the interaction of the robot with the environment • Not preprogrammed • Agent is the result of its history • Exploit the dynamics of the system • More adaptive : developmental mechanisms • Diversity Compliance: • Exploiting ecologicol niche / behavioral diversity • Exploration/Exploitation trade off

  10. Embodied AI: Principles • Parallel, loosely coupled processes • Intelligence emerge from a lager number of parallel processes • Processes are connected to the agent‘s sensory-motor aparatus • Coupling through embodiment or coordination • No functional decompositon/hierarchical control like in traditional robotic • Supsumption architecture [brooks86] • Sensory-Motor Coordination • Structuring sensory input • Generation of good sensory-motor patterns: • Correlated • Stationarity • Can simplify learning • Dimensionality Reduction of sensory-motor space [lungeralla05, boekhorst03]

  11. Embodied AI: Principles • „Morphological“ Computation • Parts of the control can be „computed“ by the morphology • Facets in flies, motion paralax • Springs and flexible material • Exploit system dynamics for control • E.g. Exploit gravity and flexible actuators • Can simplify control considerably • Increase learning speed by morphology • „Extreme“ Example: Passive dynamic walker • Cheap Design: • Exploit physics and constraints of ecological niche • Use the most simple architecture for a given task

  12. Embodied AI: Principles • Redundancy: • Overlap of functionality in the subsystems • Sensory system, Motor system • Required for diversity and adaptivity • Ecological Balance: • Complexity of the sensory, motor and neural system has to match for a given task • Balance between morphology, materials and control [Ishiguro03] • Value Principle • Motivation of the robot to do something (should be more general than RL) • Essential for every complete autonomous agent • No generally accepted solution exists • 2 approaches will be discussed in more detail

  13. Traditional Robotics / AI • In difference to traditional robotics • Limited numbers of degrees of freedom (e.g. wheels) • Stiff structure and joints (servo motors) • Easy to control • All Computation has to be done by the control system • Limited natural dynamics • Centralized rule-based control • Functional decomposition • „Sense-think-act“ cycle • Problems: • Frame problem • Symbol grounding problem

  14. Sensory-Motor coordination (SMC)[Pfeifer99, Lungarella05] • Used for categorization • Traditional approach: Sensory-input to category mapping • Prototype or example matching • Difficulties: Often this mapping is not learnable • Noise and Inaccuracies in Sensors • Ambigious sensory input (Type 2 problems)

  15. Categorization: Example [Nolfi97] • Learn 2 categories (Wall, Cylinder) with IR sensors • Data for: • 180 orientations, 20 distances • Learn with neural network • Just linear output units • 4 resp 8 hidden neurons • Very bad results: 35 % correct categorization Back dots: correct categoritization

  16. SMC: Categorization • Approach the problem through interacting with the environment • Object related actions to structure the input • Simplifies the problem of categorization • No real internal category representation • Just different behaviors for different categories • Empirical studies about Dimensionality Reduction [lungarella05] • Example in infants: Look at object from different directions in the same distance

  17. SMC: Example • Learning optimal categorization strategy through a genetic algorithm • Nolfi‘s experiment: • Fitness: Time the robot is near the cylinder • Evolved Behavior: • Robot never stops in front of target: • Move back/forth and left/right hand side

  18. SMC: Example • Learning to distinguish circles and diamonds [Beer96] • Catching circles, avoiding diamonds • Agent can only move horizontally • Again evolved controller

  19. SMC: Example • Results: • Not merely centering and statically pattern matching • Dynamic strategy, with active scanning • Both policies evolve sensory-motor coordination strategies • Examples show quite good the idea of sensory-motor coordination • Other examples: • Darwin II [Reeke89] • Garbage Collector [Pfeifer97, Schleier96] Catching Circle Avoiding Diamond

  20. SMC: Conclusion • Nice new ideas for categorization tasks and robotics in generell • Simple examples that illustrate the use of SMC for categorization • Examples are „well-suited“ for SMC • No complex categorization problem (e.g for visual object recognition) found in the literature • Only numerical results which proofs dimensionality reduction • How to use them? • Critic: Humans are also able to do categorization very well without sensory-motor interaction • The emphasis of SMC is a bit overstressed by the authors

  21. Value Systems & Developmental Learning [oudeyer04/05, steels03] • Intrinsic Motivation of the Agent: • learn more about the environment • Ideal case: open-end learning • Many different behaviors may emerge • Very adaptive • 2 approaches to this problem discussed in more detail • Intelligent Adaptive Curiosity (IAC) [oudeyer04] • Autotelic Principle [steels03] • Still in the beginning, only for toy examples • Other approaches comming from RL • Intrinsically motivated RL [singh04] • Self Motivated Development [schmidhuber05]

  22. IAC: Motivation • Push agent towards situations in which it maximizes learning progress • Balance between the „unknown“ and the „predictable“ • Goal: Improve prediction machine • A(t) … action • SM(t)… sensory-motor context • S(t+1)… prediction

  23. IAC: framework • Prediction error • => Decrease E(t) • First naive approach • Learning Progress • Em(t)… mean Error at time t • Do not reward high error values, reward high LP • Meta Learning Machine (predicts error) • Choose action which maximizes Learning Progress • Problem ?

  24. IAC: • Problem of naive approach: • Transition from complex, not predictable situations to simple situations is considered as learning progress • Solution: • Instead of comparing the LP succesive in time, compare the LP succesive in state space

  25. IAC: algorithm • Prediction machine P • Consists of a set of local experts. • Each expert consists of training examples • Simple NN algorithm is used for prediction • Build kd-tree incrementally : experts in the leaves • Each expert stores prediction errors and the mean • Calculate local learning progress • LPi(t) = -(Empi(t) – Empi(t – DELAY) • Used for action selection • Very simple algorithms used • More sophisticated algorithms have a good chance to improve performance

  26. IAC: experiments • Toy example: • 2 wheeled robot, can produce sound • Toy: position depends on sound frequency intervall • f1 : moves randomly • f2 : stops moving • f3 : toy jumps to robot • Predictor: predict relative position of the toy

  27. IAC: experiments • Results: • Basically 3 experts • First explores intervall f3, then intervall f2 • f1 is not explored : not predictable

  28. IAC: experiments • Playground experiment • AIBO robot on a baby play mat • Various toys: can be bitten, bashed or simply detected

  29. IAC: Playground Experiment • Motor Control: • Turning head (2 DoF, pan + tilt) • Bashing (2 DoF, strength + angle) • Crouch + Bite (1 DoF, crouches given distance in direction it is looking at) • Perception: • 3 High level sensors (just binary values) • Visual object detection • Biting Sensor • Infra-red distance sensor • Bashing + Biting only produce visible results if applied in front of an appropriate object • Agent knows nothing about sensorimotor affordances

  30. IAC: Results • Different stages evolves • Stage 1: random exploration + body babbling • Stage 2: Most of the time looking around (no biting + bashing) • Stage 3: biting and bashing • Sometimes produces something, robot still not oriented to objects • Stage 4: Starts to look at objects • Learns precise location of the object • Stage 5: Trying bite biteable object, trying to bash bashable object

  31. The Autotelic principle [steels03] • Autotelic activities: no real reward • Climbing, painting… • Motivational driving signal comes from the individual itself • Balance between high challenge and required skill • too high: withdrawal • too low: boredom • Operational description given in [steels03], no real experiments found

  32. Autotelic Principle: Operational Descripion • Agent: • Organised in number of sub-agencies (components) • Establish input/output mapping based on knowledge • Each component must be parameterized to self adjust challenge levels • Precision of movement, weights of objects… • Parameter vector pi for each component • Goal: not to reach a stable state, keep exploring parameter landscape • Each component has also an associated skill vector

  33. Autotelic Principle: Operational Descripion • Self Regulation: • Operation phase: Clamp challenge parameters, learn skills through learning • Shake-Up phase: • Increase challenge: skill level already too high • Decrease challenge: performance could not be reached

  34. Conclusion: Value Systems • Both approaches try to create open-ended learner • Interesting ideas • Only very simple algorithms used, or not even implemented • Open for improvement • Can help to structure learning progress in complex environments • Complete autonomous agents will need some sort of developmental value system • No complex real-world experiments found • Scalable?

  35. Conclusion: Embodied Intelligence • Provides new ways of thinking about robotic / intelligence in general • Provides a better understanding of intelligent behavior by modelling the behavior. • Good principles to design an agent • Claims to solve many problems of traditionial AI • Good and promising ideas • Somehow the algorithmic solutions for more complex systems are missing • Actually: same problems as for traditional AI • Works for small problems • Hard to scale up

  36. The End • Thank you!

  37. Literature • [pfeifer99] R. Pfeifer and C. Schleier, Understanding Intelligence, MIT Press • [iida03] F. Iida and R. Pfeifer, Embodied Artificial Intelligence • [kirchner05] D. Spenneberg, F. Kirchner, Embodied Categorization of spatial environments on the Basis of Proprioceptive Data, AMAM 2005 • [ritzmann05] R. Ritzmann, R. Quinn, Convergent Evolution and locomotion through complex terrain by insects, vertebrates and robots, AMAM 2005 • [menciassi05] A. Menciassi, S. Spina, Bioinspired robotic worms for locomotion in unstructered environments, AMAM2005 • [ishiguro05] A. Ishiguro, M. Shimizu, Slimebot: A Modular robot that exhibits amoebic locomotion, AMAM2005 • [albiez05] J. Albiez, T. Hinkel, Reactive Foot-control for quadruped walking, AMAM2005 • [boblan05] I. Boblan, R. Bannasch, A Humanlike Robot Arm and Hand with fluidic muscles: The human muscle and the control of technical realization, AMAM 2005 • [lungeralla05] M. Lungarella, O. Sporns, Information Self-Structuring: Key Principle for Learning and Development • [broekhorst03] R. Broekhorst, M. Lungarella, Dimensionality Reduction through sensory motor-coordination

  38. Literature • [ishiguro03] A. Ishiguro, T. Kawakatsu, How should control and body systems be coupled? A robotic case study, Embodied artificial intellingence 2003 • [nolfi97] S. Nolfi, Evolving non-trivial behavior on autonomous robots: Adaptation is more powerful than decompositionand integration • [beer96] R. Beer, Toward the Evolution of Dynamical Neural Networks for Minimally Cognitive Behavior • [reeke89] G. Reeke, O. Sporns, Synthetic neural modeling: A multilevel approach to analysis of brain complexity • [pfeifer97] R. Pfeifer, C. Schleier, Sensory-motor coordination: The metaphor and beyond: Practice and future of autonmous robots • [schleier96] C. Schleier, D. Lambrinos, Categorization in a real world agent using haptic exploration and active perception • [oudeyer04] P. Oudeyer, F. Kaplan, Intelligent Adaptive Curiosity: a source of Self-Development • [oudeyer05] P. Oudeyer, F. Kaplan, The Playground Experiment: Task independent development of a curious robot. • [steels03] L. Steels, The Autotelic Principle • [singh04] S. Singh, A. Barto, Intrinsically Motivated Learning of Hierarical Collections of Skills • [schmidhuber05] J. Schmidhuber, Self-Motivated Development Through Rewards for Predictor Errors/Improvements

  39. Measure influence of SMC [lungeralla05, broekhorst03] • New experiments with SMC • Measure the effect of SMC with information processing quantities • Experiments of Broekhorst: • Robot: • Wheeled • CCD camera (compressed to 10 x 10 pixels) • IR sensors (12) • Measure angular velocity • 5 different Experiments: • Control setup: Move forward • Moving object • Wiggling : Move forward in oscillatory movement • Tracking 1: Move forward + track object • Tracking 2: Move forward + track moving object • Preprogrammed control

  40. Measure Influence of SMC [broekhorst03] • Quantify dimension of the sensory information • Measure Correlation on most significant principal components from the different modalities (R*) • 3 different information quantities • Shannon entropy • Dominance of the highest eigenvector • Number of PC‘s that explain 95% of variance …Eigenvalue of R*

  41. Results: • Difference: • Variance in the experiments • SMC experiments have higher variance • SMC experiments and non SMC experiments can be distinguished • No further straithforward results

  42. Measure Influence of SMC [lungarella05] • Experimental Setup: • Active Vision: (compressed 55 x 75 pixels) looking at screen • 2 behaviors: • Foveation: „follow red area“ • Random: Same motion structure, not coordinated • 2 scenarios • Artificial Scene: Random Data with moving red block • Natural Images

  43. Measure Influence of SMC [lungarella05] • Quantify sensory information • Entropy • Joint-Entropy • Mutual Information • Integration : Multivariate Mutual Information • Complexity : • Quantify Dimensionality Reduction • PCA • Isomap ([tenenbaum01], also recognizes non-linear dimensions)

  44. Results for foveation behavior • Entropy in central regions decreased • Mutual information increased

  45. Results for foveation behavior • Integration and Complexity where much larger in the center

  46. Results for foveation behavior • Reduced dimensionality (isomap) • Mutual information between center and motor actions also increased

More Related