With a background in Robot Control, my primary interests are in sensori-motor control techniques of embodied systems. In particular, I am interested in the dimensionality reduction techniques for motor control of redundant/compliant robot systems inspired by nature.
I am also interested in various aspects of robot mechanical and electronic design.

I am a member of the following projects :

1. RobotDoc : An EU Marie Curie Network project, investigating the development of different sensorimotor and cognitive capabilities in humanoid robots.  In the context of the project, I shall be studying a "Quantitative framework for sensory-motor strategies". In particular I am working on learning Movement Primitives, and on understanding and exploiting body dynamics and material properties to self-learn and optimise motor behaviour for humanoid robots.

2. Octopus: An EU FP7 Project which aims to investigate and understanding the principles that give rise to the octopus sensory-motor capabilities and incorporating them in new design technologies to build an embodied artefact, based broadly on the anatomy of the 8-arm body of an octopus, and with similar performance in water, in terms of dexterity, speed, control, flexibility, and applicability.

It might seem a pretty tall order considering the current state-of-the-art but keep watching this space folks!

Active Projects:

1. Motor Primitive inspired Reduced Order Control of Redundant Robots : Inspired by neuroscientific theories of biological motor primitives and spinal force fields, I am trying to propose a control architecture for redundant (and compliant) robots based on reduced-dimensional control. Utilising tools from Model Order Reduction, and ideas from developmental psychology, the aim is to have a self-learning architecture that is tightly coupled to the sensors, actuators and the dynamics of the robot body.

2.  Curvature Dynamic Model for Continuum Robot arms : Models of continuum systems are difficult to develop and not straight forward to control. Inspired by the reduced dimensionality in the Peripheral Motor System of the Octopus, I am trying to build reduced order models of the behaviour using flexure (curvature) sensing.The aim is to then utilise such a reduced order model to simplify the control problem of octopus arm reaching.

3. DMP for Humanoids : I am researching the learning of Dynamical Movement Primitives for humanoid robots, and in particular, effect of body properties.

Shelved Projects

1. Mag-E Actuation : We are trying to design an actuator for fin-based locomotion based on the principles of  electromagnetism. This design will allow us to study energy efficient actuation using passive properties of the underlying magneto-mechanical system and develop simple control strategies exploiting the inherent nonlinearity of the system. This is a colloboration with Mr. Juan Pablo Carbajal.  This project has now shifted to become a simulated study on this mode of actuation aimed at achieving energy optimality in swimming.

2. Passive Silicone octopus-like arms and String Pullers : The first target in the Octopus Project s to come up with an effective design for actuation  of soft-bodied arms which can replicate the prototypical behaviours of the natural octopus like reaching and grasping. We are  trying to understand the passive properties of silicone and how this can aid us in the design and actuation of the string pulling arms, which are basically tendon driven silicone structures with inextensible strings simulating muscle contraction in longitudinal and transverse directions. This is a colloboration with Mr. Matteo Cianchetti of the ARTS Lab of Scuola Superiore Sant'Anna, Italy. I am now working on model validation using a curvature based measure on the real silicone robot arms.

Fall 2011 

•   Introduction to Artificial Intelligence, Prof. Dr. Rolf Pfeifer

Fall 2010 :

• Introduction to Artificial Intelligence, Prof. Dr. Rolf Pfeifer

Spring 2010:

• Bio-inspired Robotics, Dr. Lijin Aryananda

Fall 2009:

• Formal Methods in Computer Science II, Prof. Dr. Rolf Pfeifer