PROJECTSUMMARY

ICT-2011-7-2.1287888

2ICT-2011-7-2.1

287888

Index

1. Consortium

2. Project overview• Project Fiche• Main concepts

3. Work packages

4. Dissemination tools

3ICT-2011-7-2.1

287888

Index

1. Consortium

2. Project overview• Project Fiche• Main concepts

3. Work packages

4. Dissemination tools

4ICT-2011-7-2.1

287888

Consortium

• Project Coordinator

• Partners

5ICT-2011-7-2.1

287888

Consortium

• Roles– Treelogic

• Project Coordinator

• Computer vision developer

• Semantic technologies expert

– Tecnalia• Technical Manager

• Cognitive system designer

• Robotic system integrator

– UOB• Quality Manager

• H-H object exchange principles

• Evaluation procedure

– SSSA• Hand control algorithms

• Robotic hand developer

– RURobots• SW methodology provider

• Scenario provider

• Exploitation expert

6ICT-2011-7-2.1

287888

Index

1. Consortium

2. Project overview• Project Fiche• Main concepts

3. Work packages

4. Dissemination tools

7ICT-2011-7-2.1

287888

Project overview

Project Fiche• Funded the European Union Seventh Framework Programme.

FP7-ICT-7-2.1 (No. 287888)• Duration:

– 36 months (November 2011 – October 2014)

• Consortium– Treelogic (Coordinator)– Tecnalia (Technical Manager)– University of Birmingham (Quality Manager)– Scuola Superiore Sant’Anna– RURobots

• EUROP SRA alignment

8ICT-2011-7-2.1

287888

Project overview

Main concepts• CogLaboration aims:

– To understand the cognition of H-H object exchange– To work in weakly controlled and natural tasks– To design physical sensing devices in a robotic hand– To implement artificial cognitive systems– To handle efficient and fluid Human-Robot object exchange

• Challenges– The adaptation of robot’s motion based on the human’s actions.– Getting the cognition of exchange beyond the kinematics and dynamics.

• Where will the exchange take place?• How will the object be presented in the hand-over?• Proactive behavior for human intentions

9ICT-2011-7-2.1

287888

Project overview

Main concepts• Scientific objectives:

– To design a model of the cognition of fluent object exchange. How?• Describing detailed scenarios and types of human users• Specifying basic performance and cognitive components of object exchange• Modeling how intentions can be detected and recognized• Modeling how gestures can be used to coordinate actions

– To describe the basic cognitive capacities needed for fluent object exchange. How?• Modeling the evolution of visual focus of attention• Modeling the typical pose, reach and grasp motions• Identifying the forces applied onto the object• Identifying failure, rescue and restore strategies

10ICT-2011-7-2.1

287888

Project overview

Main concepts• Technical objectives:

– To develop a set of vision modules• Characterizing objects and human postures

– To design a robotic hand • Equipped with compliant sensory fingers• Level of sensitivity in accordance to the required force magnitude

– To assemble the robotic hand with a robotic arm• Human arm-like kinematics

– To implement a control architecture based on cognitive neuroscience• Implementing arm motor algorithms with real-time continuous tuning• Implementing hand grasp/actions control algorithms

11ICT-2011-7-2.1

287888

Index

1. Consortium

2. Project overview• Project Fiche• Main concepts

3. Work packages

4. Dissemination tools

12ICT-2011-7-2.1

287888

Work packages

WP1 Project Management

WP3 Scene and Situation Understanding

WP4 Control Architectures based on Cognitive Neuroscience

WP

6 A

rtif

icia

l Co

gn

itiv

e S

yste

m

Eva

luat

ion

WP5 Artificial Cognitive System Integration

WP7 Dissemination and Exploitation

13ICT-2011-7-2.1

287888

Work packages

WP2 – Cognitive Principles of H-H Object Exchange• Objective

– Understand the HH object exchange cognitive process to identify and model critical parameters.

– Execute behavioral studies in different conditions

• Outcomes– Set of quantitative requirements

• Arm & hand trajectories, velocity & acceleration

• Force variation during handover

– Qualitative user feedback– Identification of the perception cues– Characterization of non verbal communication flow

14ICT-2011-7-2.1

287888

Work packages

WP3 – Scene and situation understanding• Objective

– Provide to the Artificial Cognitive System all the visual information to trigger control actions according to neuroscience model

– Achieving a visual understanding from the object and the human body

• Outcomes– Object recognition and tracking module– Pose estimation and hand tracking– Handling knowledgebase

15ICT-2011-7-2.1

287888

Work packages

WP4 – Neuroscience-based control architecture• Objective

– Design a bio-inspired controller focusing on object exchange to provide a human-like motion behaviour

– Implement a hierarchical decision-making process

• Outcomes– Hand motion control system – Cognitive Architecture able to

• Recognize the intended human motion and define the suitable robot trajectory (low frequency)

• Locally adapt the defined motion pattern to the observed human behavior (high frequency)

16ICT-2011-7-2.1

287888

Work packages

WP5 – Artificial cognitive systems integration• Objective

– Provide the physical systems – Software and hardware integration

• Outcomes– Physical prototype – Hand sensory system

• Hardware integration

• Software integration

17ICT-2011-7-2.1

287888

Index

1. Consortium

2. Project overview• Project Fiche• Main concepts

3. Work packages

4. Dissemination tools

18ICT-2011-7-2.1

287888

Dissemination tools

Public Website• http://coglaboration.eu

Twitter• https://twitter.com/coglaboration

SlideShare• http://www.slideshare.net/coglaboration

Project Management Office• info@coglaboration.eu

ICT-2011-7-2.1287888