Mitarbeiter

M. Sc. Daniel Hohnloser

Kontakt

Publikationen

2016

  • T. Lieske, D. Schuklin, D. Hohnloser, M. Reichenbach, B. Pfundt, D. Fey, and R. Weigel, "Smart Sensor Framework: A Pressure Sensor for Smart Home Applications" in 1. E|HOME-CENTER SYMPOSIUM, Nürnberg, Germany, 2016. [Bibtex]
    @inproceedings{lieske2016,
    author = {Lieske, Tobias and Schuklin, Dennis and Hohnloser, Daniel and Reichenbach, Marc and Pfundt, Benjamin and Fey, Dietmar and Weigel, Robert},
    language = {English},
    booktitle = {1. E|HOME-CENTER SYMPOSIUM},
    cris = {https://cris.fau.de/converis/publicweb/publication/108935244},
    year = {2016},
    month = {12},
    day = {30},
    eventdate = {2016-11-30/2016-12-01},
    faupublication = {yes},
    peerreviewed = {unknown},
    title = {Smart Sensor Framework: A Pressure Sensor for Smart Home Applications},
    type = {Konferenzschrift},
    venue = {Nürnberg, Germany},
    }
  • D. Schuklin, D. Hohnloser, T. Lieske, M. Reichenbach, A. Bänisch, B. Pfundt, J. Röber, R. Weigel, and D. Fey, "Systemkonzept eines autarken und intelligenten Miniatur-Sensors für Smart Home" in VDE Kongress 2016: Internet der Dinge, 2016. [Bibtex]
    @inproceedings{shuklin2016,
    abstract = {Trotz der erheblichen Fortschritte im Bereich Smart Home, stellt die Installation von Hunderten von Sensoren eine der größten Herausforderungen dar. Eine mögliche Lösung für dieses Problem ist die Integration aller Komponenten innerhalb einer integrierten Schaltung. Dieser Beitrag stellt ein Konzept für ein intelligentes Sensorsystem dar, welches die wichtigsten Sensoren für das intelligente Zuhause (wie z.B. Drucksensor, Gassensor, Temperatur-, oder Lichtsensor) auf einem Chip vereint. Dadurch wird das Messen von lokalen Temperaturen, Lichtverhältnissen, Drucks und sogar Luftqualität ermöglicht. Mit diesen umfassenden Informationen können lebensunterstützende Systeme, Einbruchsdetektion, automatisierte Klimaregelung und Beleuchtungssteuerung in Räumen und vieles mehr realisiert werden. Langfristiges Ziel dieser Arbeit ist die Entwicklung eines selbst organisierenden und autonomen Netzwerks von intelligenten Sensoren im Bereich Smart Home. Mit Abmessungen von wenigen Zentimetern, kann jeder Sensor nahezu überall angebracht werden, wie zum Beispiel an einem Fenster.},
    author = {Schuklin, Dennis and Hohnloser, Daniel and Lieske, Tobias and Reichenbach, Marc and Bänisch, Andreas and Pfundt, Benjamin and Röber, Jürgen and Weigel, Robert and Fey, Dietmar},
    booktitle = {VDE Kongress 2016: Internet der Dinge},
    cris = {https://cris.fau.de/converis/publicweb/publication/119421544},
    year = {2016},
    month = {11},
    eventtitle = {VDE Kongress 2016: Internet der Dinge},
    faupublication = {yes},
    keywords = {Smart Home; Intelligent Sensor System; MEMS Sensor; Analog to Digital Converter; Digital Processing Unit},
    peerreviewed = {Yes},
    title = {Systemkonzept eines autarken und intelligenten Miniatur-Sensors für Smart Home},
    }
  • D. Hohnloser, D. Schuklin, C. Schmidt, M. Kreitmaier, M. Blasini, A. Hagelauer, and R. Weigel, "Feasibility Analysis of a Novel Production Method for Monolithic Integrated MEMS with Nanogaps" in IEEE Sensors, Orlando, FL, USA, 2016, pp. 1-3. [DOI] [Bibtex]
    @inproceedings{hohnloser2016,
    abstract = {This paper analyses a novel production technique for the fabrication of microelectromechanical system (MEMS) with a gap in the scale of nanometer. The technology is based on a density-changing layer, which let a gap arise through the shrinkage of this layer. After the description of the technology, the requirements for monolithic integration and CMOS compatibility with respect to this technology are worked out. It has been discovered that there are several challenges to be overcome, especially to find a material composition which match the requirements will be important as well as to set up the process without affecting other CMOS device parameters. But if these challenges are solved the process will be suitable for various applications and enable to open up new markets.},
    author = {Hohnloser, Daniel and Schuklin, Dennis and Schmidt, Carsten and Kreitmaier, Michael and Blasini, Mario and Hagelauer, Amelie and Weigel, Robert},
    publisher = {IEEE},
    booktitle = {IEEE Sensors},
    cris = {https://cris.fau.de/converis/publicweb/publication/108092424},
    year = {2016},
    month = {10},
    day = {30},
    doi = {10.1109/ICSENS.2016.7808655},
    eventdate = {2016-10-30/2016-11-02},
    faupublication = {yes},
    keywords = {MEMS; NEMS},
    pages = {1--3},
    peerreviewed = {Yes},
    title = {Feasibility Analysis of a Novel Production Method for Monolithic Integrated MEMS with Nanogaps},
    venue = {Orlando, FL, USA},
    }

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