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Integration of a GFDM Secondary System in an OFDM Primary system

Michailow, Nicola ; Lentmaier, Michael LU ; Rost, Peter and Fettweis, Gerhard (2011) Future Network and Mobile Summit (FNMS)
Abstract
Concepts of cognitive radio are yet in an early stage of development. They aim at improving the efficiency of spectrum utilization by exploiting locally and temporally vacant parts of the spectrum. When hierarchical spectrum access is considered, secondary users are authorized to use spectrum white spaces on a non-interfering basis, where minimal impact on the primary systems has to be ensured. GFDM is a digital multi-carrier transceiver concept that employs pulse shaping filters to provide control over the transmitted signal's spectral properties, a cyclic prefix that enables an efficient FFT-based frequency domain equalization scheme as well as tail biting as a way to make the prefix independent of the filter length. In this paper, two... (More)
Concepts of cognitive radio are yet in an early stage of development. They aim at improving the efficiency of spectrum utilization by exploiting locally and temporally vacant parts of the spectrum. When hierarchical spectrum access is considered, secondary users are authorized to use spectrum white spaces on a non-interfering basis, where minimal impact on the primary systems has to be ensured. GFDM is a digital multi-carrier transceiver concept that employs pulse shaping filters to provide control over the transmitted signal's spectral properties, a cyclic prefix that enables an efficient FFT-based frequency domain equalization scheme as well as tail biting as a way to make the prefix independent of the filter length. In this paper, two setups of uncoded AWGN transmission are analyzed through simulation. Both setups have in common that an OFDM primary system is overlaid by a secondary system. For that purpose, resources are made free artificially. First, a non-synchronized OFDM system is inserted into the white space. Then, the results are compared to the case when the secondary system operates with the GFDM scheme. Both setups are reviewed under the aspect of bit error performance in dependence of guard bands and various pulse shaping filter parameters. Conclusions for the primary and secondary system are drawn. (Less)
Please use this url to cite or link to this publication:
author
; ; and
organization
publishing date
type
Chapter in Book/Report/Conference proceeding
publication status
published
subject
keywords
GFDM, multicarrier transmission, OFDM, cognitive radio
host publication
2011 Future Network & Mobile Summit
publisher
IEEE - Institute of Electrical and Electronics Engineers Inc.
conference name
Future Network and Mobile Summit (FNMS)
conference location
Warsaw, Poland
conference dates
2011-06-15 - 2011-06-17
external identifiers
  • scopus:84255177389
ISBN
978-1-4577-0928-9
language
English
LU publication?
no
id
62c068b8-a012-4636-af0e-3e9498433fb8 (old id 3731171)
alternative location
http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6095270
date added to LUP
2016-04-04 10:57:58
date last changed
2022-02-06 06:32:31
@inproceedings{62c068b8-a012-4636-af0e-3e9498433fb8,
  abstract     = {{Concepts of cognitive radio are yet in an early stage of development. They aim at improving the efficiency of spectrum utilization by exploiting locally and temporally vacant parts of the spectrum. When hierarchical spectrum access is considered, secondary users are authorized to use spectrum white spaces on a non-interfering basis, where minimal impact on the primary systems has to be ensured. GFDM is a digital multi-carrier transceiver concept that employs pulse shaping filters to provide control over the transmitted signal's spectral properties, a cyclic prefix that enables an efficient FFT-based frequency domain equalization scheme as well as tail biting as a way to make the prefix independent of the filter length. In this paper, two setups of uncoded AWGN transmission are analyzed through simulation. Both setups have in common that an OFDM primary system is overlaid by a secondary system. For that purpose, resources are made free artificially. First, a non-synchronized OFDM system is inserted into the white space. Then, the results are compared to the case when the secondary system operates with the GFDM scheme. Both setups are reviewed under the aspect of bit error performance in dependence of guard bands and various pulse shaping filter parameters. Conclusions for the primary and secondary system are drawn.}},
  author       = {{Michailow, Nicola and Lentmaier, Michael and Rost, Peter and Fettweis, Gerhard}},
  booktitle    = {{2011 Future Network & Mobile Summit}},
  isbn         = {{978-1-4577-0928-9}},
  keywords     = {{GFDM; multicarrier transmission; OFDM; cognitive radio}},
  language     = {{eng}},
  publisher    = {{IEEE - Institute of Electrical and Electronics Engineers Inc.}},
  title        = {{Integration of a GFDM Secondary System in an OFDM Primary system}},
  url          = {{https://lup.lub.lu.se/search/files/5662909/3731177.pdf}},
  year         = {{2011}},
}