Marc Stelzner

@INPROCEEDINGS{Geyer2018BloodVoyagerS,
AUTHOR={Regine Geyer and Marc Stelzner and Florian {B{\"u}ther} and Sebastian Ebers},
TITLE={{BloodVoyagerS} - Simulation of the work environment of medical nanobots},
BOOKTITLE={5th ACM International Conference on Nanoscale Computing and Communication 2018 (ACM NanoCom'18)},
ADDRESS={Reykjavik, Iceland},
YEAR={2018},
MONTH={Sep},
DAYS={5},
PAGES={},
ISBN={},
URL={https://dx.doi.org/10.1145/3233188.3233196},
KEYWORDS={Nanonetworks; Simulation; Medical Application; Nano medicine,NCN},
ABSTRACT={The simulation of nanobots in their working environment is crucial to
promote their application in the medical context. Several simulators for
nanonetworks investigate new communication paradigms at nanoscale. However,
the influence of the environment, namely the human body, on the movement
and communication of nanobots was not considered so far. We propose a
framework for simulating medical nanonetworks, which integrates a
nanonetwork simulator with a body simulator. We derive requirements for a
body model that forms the basis for our prototypical implementation of the
body simulator BloodVoyagerSas part of the network simulator ns-3. An
evaluation shows that BloodVoyagerS successfully moves nanobots in the
simulated cardiovascular system. After about 7 minutes, the nanobot
distribution reaches a dynamic equilibrium. The prototype shows promise to
provide a more realistic full-body simulation to investigate movement and
communication of nanobots in medical applications.}
}

@inproceedings{Stelzner2018Routing,
  author={Marc Stelzner and Fabian Busse and Sebastian Ebers},
  title={In-Body Nanonetwork Routing based on {MANET} and {THz}},
  booktitle={5th ACM International Conference on Nanoscale Computing and Communication 2018 (ACM NanoCom'18)},
  address={Reykjavik, Iceland},
  year={2018},
  month={Sep},
  days={5},
  numpages={6},
  doi={10.1145/3233188.3233197},
  isbn={978-1-4503-5711-1/18/09},
  keywords={Routing; Nanonetworks; Algorithm; Hop Count; Identity-Free, NCN},
  abstract={Devices at the nanoscale are envisioned to be used in medical applications
to detect and treat diseases within a human body. However,
due to its severe resource constraints, a nanoscale device might not
execute complex tasks on its own. For this, we envision a medical
nanonetwork, comprising an in-body network built of nanonodes
and a Body Area Network (BAN) built of macroscale devices coordinating
and controlling the nanonodes. Due to the characteristics
of the in-body network and its nodes, conventional routing protocols
for macroscale mobile ad-hoc networks (MANET) are not directly
applicable and novel approaches are needed. However, since
a nanonetwork shares some characteristics of macroscale MANETs,
we identied promising protocols and evaluated their suitability for
nanonetworks using THz communication. We define requirements
for their applicability and compared their performance.}
}

@INPROCEEDINGS{Stelzner18EWME,
author={Marc Stelzner and Thomas Eisenbarth},
title={IT Security in Lübeck – The design of a modern and future-proof security curriculum},
booktitle={12th European Workshop on Microelectronics Education (EWME 2018)},
year={2018},
month={Sep.},
pages={79-82},
publisher={IEEE},
doi={10.1109/EWME.2018.8629494},
ISSN={9781538691151},
keywords={Computer science;Education;Hardware;Computer security;Software reliability;IT Security;degree program;bachelor;master;education;security by design, NCN}
}

@INPROCEEDINGS{Stel1809:Nanoscale,
AUTHOR={Marc Stelzner and Kim Scharringhausen and Sebastian Ebers},
TITLE={Nanoscale Diagnostic Procedures - Sensing inside the human body},
BOOKTITLE={5th ACM International Conference on Nanoscale Computing and Communication
2018 (ACM NanoCom'18)},
ADDRESS={Reykjavik, Iceland},
YEAR={2018},
MONTH={sep},
DAYS={5},
PAGES={},
ISBN={},
KEYWORDS="sensor; nanodevice; diagnostic procedures; medicine; NCN",
ABSTRACT="The application of nanotechnology in medicine is envisioned for detecting
and treating diseases. In literature, the ability of nanodevices to sense
their environment is taken for granted and precondition for application
scenarios. However, how this is done and which diagnostic procedures
actually benefit from the application of properly qualified nanodevices is
rarely stated. In this paper, we distinguish four traditional diagnostic
procedures and introduce our evaluation of how nanonodes may benefit from
quantitative procedures."
}

@inproceedings{Buether2017Formal,
author={Florian Büther and Florian Lau and Marc Stelzner and Sebastian Ebers},
title={A Formal Definition for Nanorobots and Nanonetworks},
booktitle={The 17th International Conference on Next Generation Wired/Wireless Advanced Networks and Systems + The 10th conference on Internet of Things and Smart Spaces (NEW2AN ruSMART 2017)},
address={St.Petersburg, Russia},
days={27},
publisher={Springer},
month={Sep},
year={2017},
url={https://dx.doi.org/10.1007/978-3-319-67380-6_20},
doi={10.1007/978-3-319-67380-6_20},
keywords={Nanorobot; Nanonetwork; Definition; Nanomachine; Machine Model,NCN,flau},
abstract={Nano computation and communication research examines nanosized devices like sensor nodes or robots. Over the last decade, it has attracted attention from many different perspectives, including material sciences, biomedical engineering, and algorithm design. With growing maturity and diversity, a common terminology is increasingly important. In this paper, we analyze the state of the art of nanoscale computational devices, and infer common requirements. We combine these with definitions for macroscale machines and robots to define Nanodevices, an umbrella term that includes all nanosized artificial devices. We derive definitions for Nanomachines and Nanorobots, each with a set of mandatory and optional components. Constraints concerning artificiality and purpose distinguish Nanodevices from nanoparticles and natural life forms. Additionally, we define a Nanonetwork as a network comprised of Nanodevices, and show the specific challenges for Medical Nanorobots and Nanonetworks. We integrate our definition into the current research of Nanodevice components with a set of examples for electronic and biological implementations.}
}

@ARTICLE{STELZNER201729,
  author = {Marc Stelzner and Falko Dressler and Stefan Fischer},
  title = {Function Centric Nano-Networking: Addressing nano machines in a medical
	application scenario},
  journal = {Nano Communication Networks},
  year = {2017},
  volume = {14},
  pages = {29 - 39},
  number = {Supplement C},
  doi = {https://doi.org/10.1016/j.nancom.2017.09.001},
  issn = {1878-7789},
  keywords = {Addressing, Internet of Nano Things, Medical application, Nano communication, NCN},
  owner = {Marc},
  timestamp = {2017.11.23},
  url = {http://www.sciencedirect.com/science/article/pii/S1878778917300042}
}

@ARTICLE{Werner2015,
  author = {Stefan Werner and Dennis Heinrich and Marc Stelzner and Volker Linnemann
	and Thilo Pionteck and Sven Groppe},
  title = {Accelerated join evaluation in Semantic Web databases by using FPGAs},
  journal = {Concurrency and Computation: Practice and Experience},
  year = {2015},
   month = {18. Mai},
  volume =    {28},
  number =    {7},
  pages =     {2031--2051},
  doi = {http://dx.doi.org/10.1002/cpe.3502}
}

@INPROCEEDINGS{stelzner2016precise,
author={Stelzner, Marc and Lau, Florian-Lennert and Freundt, Katja and Florian Büther and Nguyen, Mai Linh and Stamme, Cordula and Ebers, Sebastian},
title={{Precise Detection and Treatment of Human Diseases Based on Nano Networking}},
booktitle={11th International Conference on Body Area Networks (BODYNETS 2016)},
address={Turin, Italy},
year={2016},
month={December},
keywords={NCN,flau},
pages={58--64},
publisher={EAI},
url={https://dl.acm.org/citation.cfm?id=3068615.3068631},
abstract={highlight, This paper presents an elaborate scenario to and detect, motivate interdisciplinary computer science involvement in nanotechnology for medical applications. Our scenario illustrates how nanotechnology can be employed to and morbidity, potentially directly treat infectious diseases as a paradigm for human disorders associated with high and mortality. Thus, more precise techniques that monitor the presence and (host-, concentration of critical marker molecules and pathogen-derived) may be applicable at an earlier stage of the disease. Moreover, since the concentration threshold varies from person to person, continuous and diagnostic, individualized monitoring of both and detect, therapeutic measures is required. To and treat diseases directly at the affected location, we propose the usage of an in-body nano network build by nano machines. To report ndings and receive commands from outside of the body, the nano network is connected to a body area network via gateways. In this paper, we discuss the capabilities of nano machinery and architecture., presents the aforementioned network},
owner={Marc},
timestamp={2017.01.31}
}

@Inproceedings{Werner14,
  author	=   {Stefan Werner and Dennis Heinrich and Marc Stelzner and Sven Groppe and Rico Backasch and Thilo Pionteck},
  title		=   {{Parallel and Pipelined Filter Operator for Hardware-Accelerated Operator Graphs in Semantic Web Databases}},
  booktitle	=   {Proceedings of the 14th IEEE International Conference on Computer and Information Technology (CIT 2014)},
  year		=   {2014},
  month		=   {September 11 - 13},
  address	=   {Xi´an, China},
  publisher	=   {IEEE},
  bibsource	=   {IFIS, Universit{\"a}t zu L{\"u}beck},
  doi = {http://doi.ieeecomputersociety.org/10.1109/CIT.2014.162},
  copyright	=   {IEEE} 
}

@Article{OJSW-v1i2n02_Groppe,
        title     = {P-LUPOSDATE: Using Precomputed Bloom Filters to Speed Up SPARQL Processing in the Cloud},
        author    = {Sven Groppe and Thomas Kiencke and Stefan Werner and Dennis Heinrich and Marc Stelzner and Le Gruenwald},
        journal   = {Open Journal of Semantic Web (OJSW)},
        issn      = {2199-336X},
        year      = {2014},
        volume    = {1},
        number    = {2},
        pages     = {25--55},
        url       = {http://www.ronpub.com/publications/OJSW-v1i2n02_Groppe.pdf},
        publisher = {RonPub UG (haftungsbeschr{\"a}nkt)},
        bibsource = {RonPub UG (haftungsbeschr{\"a}nkt)}
    }