Innovatice technologies for relative navigation and capture

Source: DFKI GmbH
Source: DFKI GmbH
Scientific Leader:
Project leader:
Dr. rer. nat. Jan Paul
Contact person:

The overall goal of the INVERITAS project is the prototypic realization of a Rendez-Vous and Capture (RvC) system and the development of the core technologies with respect to the technology readiness level. The main parts of the DFKI RIC in INVERITAS are in the area of evaluation and simulation in hard- and software.

Duration: 01.05.2009 till 31.03.2012
Donee: DFKI GmbH
Sponsor: German Aerospace Center e.V.
Federal Ministry of Economics and Technology
Grant number: This project is funded by the Space Agency (DLR Agentur), acting on a mandate from the Federal Government, grant no. 50RA0910
Partner: EADS Astrium
Application Field: Space Robotics
Related Robots: KUKA KR 60
KUKA KR 60-3 Robotic arm
SpiderCam Cable Robot

Project details

Schematic representation of the long-distance movement simulation system (Source: DFKI GmbH)
long-distance movement simulation system in 3D (Source: DFKI GmbH)
hardware-/software-demonstration, conversion from 12D to 9D (Source: DFKI GmbH)

INVERITAS is a joint project including the partners EADS-ASTRIUM, Jena-Optronik and the Robotics Innovation Center of the German Research Center for Artificial Intelligence (RIC DFKI Bremen).

The main goal of INVERITAS is the prototypic realization of a broad-spectrum rendezvous and capture (RvC) system and the development of the necessary core technologies with respect to the improvement of the technology readiness level (TRL) up to TRL4 (demonstration on the surface). All fundamental technologies necessary to engineer a capture-satellite will be developed. This satellite has to be able to capture other, possibly uncooperative (due to prior damage or failure) satellites in orbit around a planetary mass, and to conduct maintenance or refueling tasks.

Primary tasks of the DFKI RIC during the INVERITAS project will be the development of a long-distance movement simulation system (LBSS) in hard- and software, and the development of alternative grasping strategies.

The LBSS will be coupled with a novel modular software simulator and a 3D-visualization. Different controllers for trajectory planning and control of the capture satellite will be implemented and evaluated. The results from the software simulation system will then be incrementally implemented on the physical LBSS in order to maintain a high compatibility of the two systems.

The physical technology demonstrators for the capture satellite and the client will be realized by a six-axis industrial robot and a cable-guided 3D-movement system which combined form the LBSS. When transmitting simulation results to the LBSS, the 12 degrees of freedom of the real capture-satellite and the client together will be converted to the limited 9 degrees of freedom of the robot and the cable-guided 3D-movement system together. The LBSS will be built into a specially fitted building which allows complete control of lighting conditions. Apart from gravity and low ambient pressure, all conditions of a real RvC-process in orbit can be simulated, evaluated, and demonstrated.

The simulation system will be used to evaluate alternative grasping strategies. Genetic algorithms will automatically evolve new kinematic systems and strategies which will improve the flexibility of such capture systems.


Inveritas: On orbit servicing Testumgebung

Autonome Reaktion des CableRobots auf die Bewegung des Roboterarms.

Inveritas: Relativnavigation und Capture

Die prototypische Realisierung eines breit einsetzbaren RendezVous und Capture Systems.

schematic structure of the core-simulation-system
schematic structure of the core-simulation-system (Source: DFKI GmbH)
evolution of new capture-strategies
evolution of new capture-strategies (Source: DFKI GmbH)
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