Engineering limit cycle systems:adaptive frequency oscillators and applications to adaptive locomotion control of compliant robots

In this thesis, we present a dynamical systems approach to adaptive controllers for locomotion control. The approach is based on a rigorous mathematical framework using nonlinear dynamical systems and is inspired by theories of self-organization. Nonlinear dynamical systems such as coupled oscillators are an interesting approach for the on-line generation of trajectories for robots with many degrees of freedom (e.g. legged locomotion). However, designing a nonlinear dynamical system to satisfy a given specification and goal is not an easy task, and, hitherto no methodology exists to approach this problem in a unified way. Nature presents us with satisfactory solutions for the coordination of many degrees of freedom. One central feature observed in biological subjects is the ability of the neural systems to exploit natural dynamics of the body to achieve efficient locomotion. In order to be able to exploit the body properties, adaptive mechanisms must be at work. Recent work has pointed out the importance of the mechanical system for efficient locomotion. Even more interestingly, such well suited mechanical systems do not need complicated control. Yet, in robotics, in most approaches, adaptive mechanisms are either missing or they are not based on a rigorous framework, i.e. they are based on heuristics and ad-hoc approaches. Over the last three decades there has been enormous progress in describing movement coordination with the help of Synergetic approaches. This has led to the formulation of a theoretical framework: the theory of dynamic patterns. This framework is mathematically rigorous and at the same time fully operational. However, it does not provide any guidelines for synthetic approaches as needed for the engineering of robots with many degrees of freedom, nor does it directly help to explain adaptive systems. We will show how we can extend the theoretical framework to build adaptive systems. For this purpose, we propose the use of multi-scale dynamical systems. The basic idea behind multi-scale dynamical systems is that a given dynamical system gets extended by additional slow dynamics of its parameters, i.e. some of the parameters become state variables. The advantages of the framework of multi-scale dynamical systems for adaptive controllers are 1) fully dynamic description, 2) no separation of learning algorithm and learning substrate, 3) no separation of learning trials or time windows, 4) mathematically rigorous, 5) low dimensional systems. However, in order to fully exploit the framework important questions have to be solved. Most importantly, methodologies for designing the feedback loops have to be found and important theoretical questions about stability and convergence properties of the devised systems have to be answered. In order to tackle this challenge, we first introduce an engineering view on designing nonlinear dynamical systems and especially oscillators. We will highlight the important differences and freedom that this engineering view introduces as opposed to a modeling one. We then apply this approach by first proposing a very simple adaptive toy-system, consisting of a dynamical system coupled to a spring-mass system. Due to its spring-mass dynamics, this system contains clear natural dynamics in the form of resonant frequencies. We propose a prototype adaptive multi-scale system, the adaptive frequency oscillator, which is able to adapt its intrinsic frequency to the resonant frequency of the body dynamics. After a small sidetrack to show that we can use adaptive frequency oscillators also for other applications than for adaptive controllers, namely for frequency analysis, we then come back to further investigation of the adaptive controller. We apply the same controller concept to a simple spring-mass hopper system. The spring-mass system consists of a body with two legs attached by rotational joints. The legs contain spring-damper elements. Finally, we present results of the implementation of the controller on a real robot, the experimental robot PUPPY II. This robot is a under-actuated robot with spring dynamics in the knee joints. It will be shown, that due to the appropriate simplification and concentration on relevant features in the toy-system the controller concepts works without a fundamental change on all systems from the toy system up to the real robot

Functional contribution of the mesencephalic locomotor region to locomotion

Parce qu'il est naturel et facile de marcher, il peut sembler que cet acte soit produit aussi facilement qu'il est accompli. Au contraire, la locomotion nécessite une interaction neurale complexe entre les neurones supraspinaux, spinaux et périphériques pour obtenir une locomotion fluide et adaptée à l'environnement. La région locomotrice mésencéphalique (MLR) est un centre locomoteur supraspinal situé dans le tronc cérébral qui a notamment pour rôle d'initier la locomotion et d'induire une transition entre les allures locomotrices. Cependant, bien que cette région ait initialement été identifiée comme le noyau cunéiforme (CnF), un groupe de neurones glutamatergiques, et le noyau pédonculopontin (PPN), un groupe de neurones glutamatergiques et cholinergiques, son corrélat anatomique est encore un sujet de débat. Et alors qu'il a été prouvé que, que ce soit lors d’une stimulation de la MLR ou pour augmenter la vitesse locomotrice, la plupart des quadrupèdes présentent un large éventail d'allures locomotrices allant de la marche, au trot, jusqu’au galop, la gamme exacte des allures locomotrices chez la souris est encore inconnue. Ici, en utilisant l'analyse cinématique, nous avons d'abord décidé d'identifier d’évaluer les allures locomotrices des souris C57BL / 6. Sur la base de la symétrie de la démarche et du couplage inter-membres, nous avons identifié et caractérisé 8 allures utilisées à travers un continuum de fréquences locomotrices allant de la marche au trot puis galopant avec différents sous-types d'allures allant du plus lent au plus rapide. Certaines allures sont apparues comme attractrices d’autres sont apparues comme transitionnelles. En utilisant une analyse graphique, nous avons également démontré que les transitions entre les allures n'étaient pas aléatoires mais entièrement prévisibles. Nous avons ensuite décidé d'analyser et de caractériser les contributions fonctionnelles des populations neuronales de CnF et PPN au contrôle locomoteur. En utilisant des souris transgéniques exprimant une opsine répondant à la lumière dans les neurones glutamatergiques (Glut) ou cholinergiques (CHAT), nous avons photostimulé (ou photo-inhibé) les neurones glutamatergiques du CnF ou du PPN ou les neurones cholinergiques du PPN. Nous avons découvert que les neurones glutamatergiques du CnF initient et modulent l’allure locomotrice et accélèrent le rythme, tandis que les neurones glutamatergiques et cholinergiques du PPN le ralentissent. En initiant, modulant et en accélérant la locomotion, notre étude identifie et caractérise des populations neuronales distinctes de la MLR. Définir et décrire en profondeur la MLR semble d’autant plus urgent qu’elle est devenue récemment une cible pour traiter les symptômes survenant après une lésion de la moelle épinière ou liés à la maladie de Parkinson.Because it is natural and easy to walk, it could seem that this act is produced as easily as it is accomplished. On the contrary, locomotion requires an intricate and complex neural interaction between the supraspinal, spinal and peripheric neurons to obtain a locomotion that is smooth and adapted to the environment. The Mesencephalic Locomotor Region (MLR) is a supraspinal brainstem locomotor center that has the particular role of initiating locomotion and inducing a transition between locomotor gaits. However, although this region was initially identified as the cuneiform nucleus (CnF), a cluster of glutamatergic neurons, and the pedunculopontine nucleus (PPN), a cluster of glutamatergic and cholinergic neurons, its anatomical correlate is still a matter of debate. And while it is proven that, either under MLR stimulation or in order to increase locomotor speed, most quadrupeds exhibit a wide range of locomotor gaits from walk, to trot, to gallop, the exact range of locomotor gaits in the mouse is still unknown. Here, using kinematic analysis we first decided to identify to assess locomotor gaits C57BL/6 mice. Based on the symmetry of the gait and the inter-limb coupling, we identified and characterized 8 gaits during locomotion displayed through a continuum of locomotor frequencies, ranging from walk to trot and then to gallop with various sub-types of gaits at the slowest and highest speeds that appeared as attractors or transitional gaits. Using graph analysis, we also demonstrated that transitions between gaits were not random but entirely predictable. Then we decided to analyze and characterize the functional contributions of the CnF and PPN’s neuronal populations to locomotor control. Using transgenic mice expressing opsin in either glutamatergic (Glut) or cholinergic (CHAT) neurons, we photostimulated (or photoinhibited) glutamatergic neurons of the CnF or PPN or cholinergic neurons of the PPN. We discovered that glutamatergic CnF neurons initiate and modulate the locomotor pattern, and accelerate the rhythm, while glutamatergic and cholinergic PPN neurons decelerate it. By initiating, modulating, and accelerating locomotion, our study identifies and characterizes distinct neuronal populations of the MLR. Describing and defining thoroughly the MLR seems all the more urgent since it has recently become a target for spinal cord injury and Parkinson’s disease treatment

Minding Nature: A Defense of a Sentiocentric Approach to Environmental Ethics

Environmental philosophers allege that philosophical views supporting the animal liberation movement are theoretically and practically inconsistent with environmentalism. While it is true that some animal ethicists argue that we ought to intervene extensively in nature such as the prevention of predation, these views take controversial positions in value theory and normative theory: (i) hedonism as a value theory, and (ii) a view of normativity which places the good before the right, e.g. maximizing utilitarianism, or a rights theory that includes strong positive rights, i.e. animals are entitled to a certain level of welfare or protection from harm. Importantly, environmental philosophers’ critiques mistakenly assume that sentience-based ethics must take these forms. I argue that there are least two angles for progress and reconciliation: (i) countenance values other than pleasure and the absence of pain, such as the value of “free” beings, come what may, or (ii) embrace a view of normativity where, unlike utilitarianism, the right is prior to the good, constraining the scope of obligation from the outset. Together or individually, these angles give shape to a workspace of animal ethical theories amenable to environmentalism. In short, I argue that a sentience-centered notion of moral considerability is correct, that several plausible views about the good and its relation to the right compatible with sentiocentrism can reconcile animal ethics with environmental ethics, and that a sentiocentric ethic constitutes an adequate environmental ethic. If this argumentative arc is on track, it provides a broad justification for the core goals of environmentalism and promises greater consilience between considered judgments about the value of wild animals and the rest of the environment

2013, UMaine News Press Releases

This is a catalog of press releases put out by the University of Maine Division of Marketing and Communications between January 2, 2013 and December 31, 2013

Maritime expressions:a corpus based exploration of maritime metaphors

This study uses a purpose-built corpus to explore the linguistic legacy of Britain’s maritime history found in the form of hundreds of specialised ‘Maritime Expressions’ (MEs), such as TAKEN ABACK, ANCHOR and ALOOF, that permeate modern English. Selecting just those expressions commencing with ’A’, it analyses 61 MEs in detail and describes the processes by which these technical expressions, from a highly specialised occupational discourse community, have made their way into modern English. The Maritime Text Corpus (MTC) comprises 8.8 million words, encompassing a range of text types and registers, selected to provide a cross-section of ‘maritime’ writing. It is analysed using WordSmith analytical software (Scott, 2010), with the 100 million-word British National Corpus (BNC) as a reference corpus. Using the MTC, a list of keywords of specific salience within the maritime discourse has been compiled and, using frequency data, concordances and collocations, these MEs are described in detail and their use and form in the MTC and the BNC is compared. The study examines the transformation from ME to figurative use in the general discourse, in terms of form and metaphoricity. MEs are classified according to their metaphorical strength and their transference from maritime usage into new registers and domains such as those of business, politics, sports and reportage etc. A revised model of metaphoricity is developed and a new category of figurative expression, the ‘resonator’, is proposed. Additionally, developing the work of Lakov and Johnson, Kovesces and others on Conceptual Metaphor Theory (CMT), a number of Maritime Conceptual Metaphors are identified and their cultural significance is discussed