main.bib

@Article{Bartels2008,
    author = {Oliver Bartels and Ernst Ahlers},
    date = {2008},
    journaltitle = {c't - Magazin für Computertechnik},
    title = {Wandelbare Funker},
    issn = {0724-8679},
    pages = {10},
    volume = {23/2008},
}

@InProceedings{Bruno2009,
    author = {M. Bruno and M. Murdy and P. Perreault and A. M. Wyglinski and J. A. McNeill},
    booktitle = {Military Communications Conference, 2009. MILCOM 2009. IEEE},
    title = {Widely tunable RF transceiver front end for software-defined radio},
    doi = {10.1109/MILCOM.2009.5379829},
    pages = {1--6},
    abstract = {In this paper, we present the design, implementation, and evaluation
 of a custom-built wideband RF front-end for enabling dynamic spectrum
 access communications in software-defined radio platforms. The frontend
 is designed for wireless operation within the 50 MHz - 2.5 GHz frequency
 range, and is entirely software-controlled by the platform. Evaluation
 of the proposed design was conducted using the Universal Software
 Radio Peripheral (USRP) software defined radio platform and controlled
 via GNU Radio software. A prototype of the design was successfully
 demonstrated over a wide range of frequencies. Finally, several remaining
 design challenges are identified that would further enhance transmission
 performance.},
    keywords = {dynamic spectrum access communications, frequency 50 MHz to 2.5 GHz, GNU Radio software, software-defined radio, software radio, transceivers, tunable RF transceiver front end, Universal Software Radio Peripheral software},
    month = {10},
    year = {2009},
}

@TechReport{Burgess2008,
    author = {David A. Burgess and Harvind S. Samra},
    institution = {Kestrel Signal Processing Inc.},
    title = {The OpenBTS Project},
    abstract = {{\"U} berblick {\"u} ber das Projekt und dessen Ziele. {\"U} berblick
     {\"u} ber die Komponenten der BTS.},
    month = oct,
    year = {2008},
}

@Book{Burns2003,
    author = {P. G. Burns},
    title = {{Software defined radio for 3G}},
    publisher = {Artech House Publishers},
    year = {2003},
}

@Book{DuqueAnton2002,
    author = {M. Duque-Anton},
    title = {{Mobilfunknetze: Grundlagen, Dienste und Protokolle}},
    publisher = {Vieweg},
    year = {2002},
}

@Manual{Ettus,
    author = {Matt Ettus},
    title = {USRP User’s and Developer’s Guide},
    organization = {Ettus Research LLC},
    owner = {ghost},
    timestamp = {2010.08.05},
}

@InProceedings{Jamadagni2000,
    author = {S. Jamadagni and M. N. Umesh},
    booktitle = {2000 IEEE International Conference on Personal Wireless Communications},
    title = {A PUSH download architecture for software defined radios},
    doi = {10.1109/ICPWC.2000.905846},
    pages = {404--407},
    abstract = {A software defined radio (SDR) is a completely configurable radio
 that can be programmed in software to define its functionality. An
 SDR handset can be modified to perform different functions at different
 times through software downloads. Software radios give the ability
 to add or remove software components or allow plug and play of software
 components. This allows the SDR handset to be specifically tailored
 to the applications expected to run on the handset resulting in great
 flexibility. The downloadable software components can be signal processing
 components, protocol components or application components. The SDR
 forum is evolving a download protocol in liaison with the MExE (mobile
 execution environment) activities of the ETSI forum. Software download
 overheads are an important issue in realizing viable software radios.
 Download requests can be initiated by the user terminal, which is
 termed as a PULL operation or the base station (or the download server)
 can initiate the download process which is termed as a PUSH operation.
 We assert that PUSH is an important mode of software download and
 explore a download architecture that involves PUSH},
    keywords = {configurable radio, download protocol, ETSI forum, MExE, mobile execution environment, mobile radio, protocols, PUSH download architecture, SDR forum, software defined radios, software download overheads, telecommunication computing},
    year = {2000},
}

@Book{Johnson2004,
    author = {C. R. Johnson and W. A. Sethares},
    title = {{Telecommunication breakdown: concepts of communication transmitted via software-defined radio}},
    publisher = {Prentice Hall},
    year = {2004},
}

@InProceedings{Nagurney2009,
    author = {L. S. Nagurney},
    booktitle = {Frontiers in Education Conference, 2009. FIE '09. 39th IEEE},
    title = {Software defined radio in the electrical and computer engineering curriculum},
    doi = {10.1109/FIE.2009.5350649},
    pages = {1--6},
    abstract = {The development of Software Defined Radio systems and their extension
 to Cognitive Radio Systems and Smart Radio Systems have introduced
 a plethora of topics and examples that can be included in the curriculum.
 The design of these software defined radio systems has less in common
 with traditional radio design and more in common with the design
 of Embedded Systems and Software Engineering. This purpose of this
 paper is to overview software defined radio from the simplest form
 to its most complicated form and give examples on how software defined
 radio concepts can be used as examples and exercises in a variety
 of Electrical Engineering and Computer Engineering courses and labs.},
    issn = {0190-5848},
    keywords = {cognitive radio systems, computer engineering curriculum, computer science education, electrical engineering curriculum, smart radio systems, software defined radio, software radio, telecommunication engineering education},
    month = {10},
    year = {2009},
}

@InProceedings{Rivet2009,
    author = {F. Rivet and Y. Deval and J.-B. Begueret and D. Dallet and P. Cathelin and D. Belot},
    booktitle = {Radio and Wireless Symposium, 2009. RWS '09. IEEE},
    title = {From Software-Defined to Software Radio: Analog Signal Processor features},
    doi = {10.1109/RWS.2009.4957351},
    pages = {348--351},
    abstract = {The RF transceivers architectures are to integrate the concept of
 software radio. But, in the case of mobile terminal, hard constraints
 are imposed by the factor of mobility. Low power and very complex
 circuits are claimed by the telecommunication industry. Classical
 architectures are no more sufficient to challenge this goal. New
 systems are thus proposed, and the concept of software defined radio
 (SDR) is a step on the roadmap toward software radio (SR). This paper
 presents a state of the art of SDR circuits and explores the application
 of a analog signal processor SR chip.},
    keywords = {analog signal processor, RF transceivers architectures, software-defined radio, software radio, transceivers},
    month = {1},
    year = {2009},
}

@InProceedings{Tribble2008,
    author = {A. C. Tribble},
    booktitle = {Radio and Wireless Symposium, 2008 IEEE},
    title = {The software defined radio: Fact and fiction},
    doi = {10.1109/RWS.2008.4463414},
    pages = {5--8},
    abstract = {In comparison to legacy systems that are typically tailored to provide
 a narrow range of capabilities through hardware, the next generation
 software defined radios are intended to implement a broader range
 of capabilities through elements that are software configurable.
 This offers the user the promise of greater flexibility, by being
 able to run more than one legacy waveform on a single platform, as
 well as a growth path to more and greater capability, such as mobile
 ad hoc networking. This presentation will examine the key architectural
 differences between software defined, and hardware defined radios,
 and will highlight some of the key challenges that must be addressed
 in fielding a software defined radio.},
    keywords = {legacy system, mobile ad hoc networking, next generation software defined radio, software radio},
    month = {1},
    year = {2008},
}

@Book{Tuttlebee2002,
    author = {Walter Tuttlebee},
    title = {software defined radio},
    publisher = {Wiley},
    year = {2002},
}

@Article{Tuttlebee1999,
    author = {W. H. W. Tuttlebee},
    title = {Software-defined radio: facets of a developing technology},
    doi = {10.1109/98.760422},
    issn = {1070-9916},
    number = {2},
    pages = {38--44},
    volume = {6},
    journal = {Personal Communications, IEEE},
    keywords = {adaptive spectrum management, common global standards, digital radio, Internet, personal communication networks, personal communications industry, real-time downloadable software, reconfigurable terminals, regional radio interfaces, software-defined radio, software engineering, software-reconfigurable universal handset, telecommunication computing, telecommunication standards, third-generation personal communications, third-generation systems, wireless industry},
    month = {4},
    year = {1999},
}

@Book{Walke2001,
    author = {B. Walke},
    title = {Mobilfunknetze und ihre Protokolle Band1},
    publisher = {B.G.Teubner},
    owner = {ghost},
    timestamp = {2010.08.04},
    year = {2001},
}

@Book{Walke2000,
    author = {B. Walke},
    title = {Mobilfunknetze und ihre Protokolle Band2},
    publisher = {B.G.Teubner},
    year = {2000},
}

@Article{Wellens2010,
    author = {Matthias Wellens and Prof. Petri Mähönen},
    title = {Intelligente Funker},
    issn = {0724-8679},
    pages = {146},
    volume = {2/2010},
    journal = {c't - Magazin f {\"u} r Computertechnik},
    month = feb,
    year = {2010},
}

@InProceedings{Yoshida1999,
    author = {H. Yoshida and H. Tsurumi and Y. Suzuki},
    booktitle = {Vehicular Technology Conference, 1999. VTC 1999 - Fall. IEEE VTS 50th},
    title = {Broadband RF front-end and software execution procedure in software-defined radio},
    doi = {10.1109/VETECF.1999.797315},
    pages = {2133-2137},
    volume = {4},
    abstract = {A software-defined radio is one of the solutions for realizing a multi-mode
 terminal for various mobile communication standards. The software-defined
 radio can be changed by replacement of the application software,
 including modems, filters, equalizers and so on. A radio terminal
 architecture fit for the ideal software-defined radio implementation
 is described. A broadband RF-stage configuration, which introduces
 the direct conversion principle, is proposed for realizing the multi-mode
 software-defined radio. A software configuration including the application
 program which does not depend on the hardware, and the basic programs
 which reconcile the differences between hardware and execution procedure,
 are also proposed},
    keywords = {broadband networks, broadband RF front-end, direct conversion, equalizers, filters, mobile communication standards, mobile radio, modems, multi-mode terminal, radio terminal architecture, software-defined radio, software execution procedure, telecommunication computing, telecommunication standards, telecommunication terminals},
    year = {1999},
}

@Misc{Wikipedia2011,
    author = {Wikipedia},
    title = {Prolog --- Wikipedia{,} Die freie Enzyklopädie},
    note = {[Online; Stand 22. Oktober 2011]},
    url = {http://de.wikipedia.org/w/index.php?title=Prolog&oldid=94982334},
    year = {2011},
}

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