Mirko Rummelhagen

Biographie

Mirko Rummelhagen ist ein erfahrener Elektrotechniker und Softwareentwickler. Im Jahr 2013 schloss er sein Studium der Elektrotechnik an der Universität Rostock mit einem Master-Abschluss ab. Mit seinem ausgeprägten Interesse an Technik und seiner Leidenschaft für Innovationen hat sich Mirko Rummelhagen als Fachmann auf dem Gebiet der Softwareentwicklung etabliert.

Mirko Rummelhagens Expertise umfasst ein breites Spektrum an Software-Lifecycle-Bereichen. Er hat an verschiedenen Projekten in den Bereichen Softwarearchitektur, Softwareentwicklung, Softwaretest und Hardwareentwicklung gearbeitet. Seine einzigartige Mischung aus technischem Wissen und praktischer Erfahrung hat es ihm ermöglicht, Softwarelösungen zu entwickeln, die sowohl effizient als auch effektiv sind.

Mirko Rummelhagen ist vom International Software Architecture Qualification Board (iSAQB) als Software-Architekt und vom International Software Testing Qualifications Board (ISTQB) als Software-Tester zertifiziert, was sein Engagement für die Bereitstellung qualitativ hochwertiger Software-Lösungen unterstreicht. Außerdem besitzt er den Ausbildereignungsschein (AdA), der ihn dazu qualifiziert, andere im Bereich der Softwareentwicklung auszubilden.

Im Laufe seiner Karriere hat Mirko Rummelhagen mit verschiedenen Organisationen in unterschiedlichen Branchen zusammengearbeitet, darunter Telekommunikation, Automobil und Raumfahrt. Seine Fähigkeit, die spezifischen Bedürfnisse und Herausforderungen jeder Branche zu verstehen, macht ihn zu einer wertvollen Bereicherung für jedes Team, mit dem er zusammenarbeitet. Mirko Rummelhagens einzigartige Mischung aus technischem Fachwissen und zwischenmenschlichen Fähigkeiten hat es ihm ermöglicht, bei einer Vielzahl von anspruchsvollen Hard- und Softwareprojekten durchweg erfolgreich zu sein.

Publikationen

Potentials and limitations of IEEE 802.11 for satellite swarms

Potentials and limitations of IEEE 802.11 for satellite swarms

DOI: 10.1109/AERO.2014.6836320

Abstract:

In the space community, there is a strong interest in formation flying or swarm missions with small satellites. This could open the door to new exciting applications in earth observation, telecommunication or in-orbit servicing. Such missions are expected to have important benefits in terms of low system and deployment costs, distributed sensor capability or high reliability due to redundancy. In order to take advantage of a swarm configuration, a communication concept is required, which deals in a generic way with specific space environments and is able to cope with frequent topology changes. Up to now, space communication has only addressed static inter-satellite links (ISL), mainly based on proprietary protocols. In this paper, we propose to adopt well-known terrestrial communication standards. Such standards have been proven to be well conceived for a wide range of applications. WiFi is one prominent representative of such candidates which includes the ability of ad-hoc networking in order to provide decentralized and distributed wireless networks. Space specific requirements demand minor adaptions of the communication protocols. COTS components are also suitable for such protocols with minor changes. This paper studies these adaptions in depth, both in theory and by simulations and is therefore an important step towards its realization. To our knowledge, there is currently no suitable communication technology which has been adapted for swarm missions with small satellites.

Analysis Of Wireless Networks for Satellite Swarm Missions

Analysis Of Wireless Networks for Satellite Swarm Missions

DOI: 10.3182/20131111-3-KR-2043.00028

Abstract:

Swarm missions are a promising approach for novel space applications, increasing operational robustness and flexibility. The communication within swarms is one main field of research in the project “BayKoSM - Bayerische Kompetenzen für Schwarm-Missionen”, which will make contributions to different technological areas of swarm missions. Swarms of small satellites in low earth orbits will be used to execute cooperative tasks. Hereby, new challenges to communication networks are arising which require investigation of specific protocols and communication devices. This paper analyses different communication and energy issues for an implementation of a swarm mission in space.

The PAC2MAN mission: A new tool to understand and predict solar energetic events

The PAC2MAN mission: A new tool to understand and predict solar energetic events

DOI: 10.1051/swsc/2015005

Abstract:

An accurate forecast of flare and coronal mass ejection (CME) initiation requires precise measurements of the magnetic energy buildup and release in the active regions of the solar atmosphere. We designed a new space weather mission that performs such measurements using new optical instruments based on the Hanle and Zeeman effects. The mission consists of two satellites, one orbiting the L1 Lagrangian point (Spacecraft Earth, SCE) and the second in heliocentric orbit at 1AU trailing the Earth by 80° (Spacecraft 80, SC80). Optical instruments measure the vector magnetic field in multiple layers of the solar atmosphere. The orbits of the spacecraft allow for a continuous imaging of nearly 73% of the total solar surface. In-situ plasma instruments detect solar wind conditions at 1AU and ahead of our planet. Earth-directed CMEs can be tracked using the stereoscopic view of the spacecraft and the strategic placement of the SC80 satellite. Forecasting of geoeffective space weather events is possible thanks to an accurate surveillance of the magnetic energy buildup in the Sun, an optical tracking through the interplanetary space, and in-situ measurements of the near-Earth environment.