MMX Rover Locomotion Subsystem - Development and Testing towards the Flight Model

Barthelmes, Stefan; Bahls, Thomas; Bayer, Ralph; Bertleff, Wieland; Bihler, Markus; Buse, Fabian; Chalon, Maxime; Hacker, Franz; Holderried, Roman; Langofer, Viktor; Lichtenheldt, Roy; Moser, Sascha; Sasaki, Kaname; Sedlmayr, Hans-Jürgen; Skibbe, Juliane; Stubbig, Leon; Vodermayer, Bernhard

doi:10.1109/aero53065.2022.9843723

Cited by 7 publications

(6 citation statements)

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“…Introduction-To assist the development of the locomotion subsystem, see [5], different simulations in the theme of driving were conducted. These simulations range from answering simple aspects like the maximum safe rover acceleration to more complex questions like an analysis of the rover's As the rover has no steered wheels, it has to rely on differential steering to navigate.…”

Section: Drivingmentioning

confidence: 99%

“…One of the critical parts of the rover is its locomotion subsystem, consisting of four individually driven wheels attached to four individually actuated legs [5]. The legs allow the rover to be put into a stowed configuration during transit.…”

Section: Introductionmentioning

confidence: 99%

“…We chose a hybrid approach for the tool selection. The implementation of the Modelica 4 modeling language in the Dymola 5 simulation framework and IDE builds the basis. On top of it are various in-house developed libraries for visualization or contact dynamics.…”

Section: Introductionmentioning

confidence: 99%

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MMX Rover Simulation - Robotic Simulations for Phobos Operations

Buse

Pignede

Bertrand

et al. 2022

2022 IEEE Aerospace Conference (AERO)

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The MMX Rover, developed by CNES and DLR, will fly to and explore the surface of the Martian Moon Phobos within the JAXA Martian Moon Exploration Mission. It will be the first wheeled locomotion system in a milli-g environment. In the development of the rover, simulations have been used to test and develop its robotic activities. This paper presents the multi-physics simulations that are being used. The overall simulator setup and its main components are discussed. To provide appropriate simulations for the various topics while maintaining a unified simulator, a modular approach was required. The different modules and their role will be outlined. For this, Dymola's implementation of the Modelica modeling language provides the basis, especially regarding multi-body dynamics, and the possibility to include external libraries, e. g. for environment interaction, control logic and visualization. Finally, examples for the simulator used in driving, uprighting, alignment and separation will be presented. These examples illustrate the approach on experiment design, setup and result evaluation. To date the MMX Rover simulator is regarded as an indispensable development and analysis tools, especially since representative lab experiments are much limited when designing a robotic system for milli-g operations. It is also planned to be used during operations phase for planning and analysis.

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Section: Drivingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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MMX Rover Simulation - Robotic Simulations for Phobos Operations

Buse

Pignede

Bertrand

et al. 2022

2022 IEEE Aerospace Conference (AERO)

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“…Furthermore, the milli-gravity on this moon -around 0.004 − 0.007m/s 2 -and the unknown surface properties make it difficult to develop a locomotion subsystem that ensures a proper movement of the rover on Phobos. More details about the mission and the locomotion subsystem development can be found in [1], [2] and [3]. A simulation view of the MMX rover on the surface of Phobos can be seen in Fig.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Upscreening of Infineon Hall Effect Sensors for the MMX rover locomotion subsystem

Sedlmayr,

Barthelmes,

Hacker

et al. 2022

2022 22nd European Conference on Radiation and Its Effects on Components and Systems (RADECS)

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The MMX (Martian Moons eXploration mission), conducted by JAXA (Japan Aerospace Exploration Agency) is supposed to explore both Mars moons Phobos and Deimos. This mission is supported by a small rover mutually developed by CNES (Centre national d'etudes spatiales) and DLR (German Aerospace Center), which is intended to land on Phobos. An essential part of that rover is the locomotion subsystem which includes several sensors and eight motors actuating the four legs and the four wheels. In each of the BLDC (Brushless DC) motors are three industrial hall effect sensors mounted which are used for incremental position sensing and motor commutation in parallel. The industrial hall effect sensors TLE 4945L from Infineon were selected instead of space qualified hall effect sensors due to the smaller form factor which is crucial for the rover and the higher accuracy. Since the motors are not located in the warmer inner compartment of the rover, extreme temperatures of -75°C up to +85 °C (non-operational) have to be survived. This temperature range extends the temperature range of industrial electronics and even space grade electronics. Therefore, an up-screening campaign was performed, were the radiation and the temperature performance of the Infineon hall effect sensors were measured. This paper highlights the most important results of the conducted tests.

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