ETD

Archivio digitale delle tesi discusse presso l'Università di Pisa

Tesi etd-11192009-160625


Tipo di tesi
Tesi di laurea specialistica
Autore
GREGORI, ANDREA
URN
etd-11192009-160625
Titolo
Joint bit allocation and precoding for filterbank transceivers in NOFDM systems
Dipartimento
INGEGNERIA
Corso di studi
INGEGNERIA DELLE TELECOMUNICAZIONI
Relatori
relatore Ing. Lottici, Vincenzo
relatore Ing. Stupia, Ivan
relatore Ing. Kliks, Adrian
relatore Prof. Giannetti, Filippo
Parole chiave
  • Multicarrier system
  • NOFDM
  • GMC
  • filterbank
  • Gabor theory
  • pulse design
  • blockfading
  • capacity
  • optimization
  • transceiver design
  • precoding
  • bit loading
  • cognitive radio
Data inizio appello
14/12/2009
Consultabilità
Completa
Riassunto
Recently, the non orthogonal frequency division multiplexing (NOFDM) systems have
attracted increased interest. They have several advantages over traditional OFDM
systems: higher bandwidth efficiency; reduced sensitivity to carrier frequency offsets,
oscillator phase noise and narrowband interference; and reduced intersymbol/intercarrier
interference (ISI/ICI). In particular, low ISI/ICI will be important for future systems
where Doppler frequencies will be larger (equivalently, channel variations will be
faster) due to higher carrier frequencies and higher mobile velocities.
In the first part of this thesis the duality of multicarrier systems and Gabor frames
is discussed and applied to the design of a generalized multicarrier system based on
a filterbank structure. The efficient polyphase implementation is also discussed.
In this thesis the channel capacity of a GMC systems is evaluated through the
diagonalization of an equivalent matrix model where intersymbol and intercarrier
interferences have been included. Exploiting the majorization theory, the mutual information
can be represented as a Schur-concave function and it is maximized through
a joint transceiver design adding a linear precoder at the transmitter and a LMMSE
equalizer at the receiver. The capacity is derived by the eigenvalue decomposition
of the global system matrix including the noise colored by the receiver filtering and
employing a power allocation of the transmitted power according to the well-known
water-filling solution.
This thesis investigates also the behaviour of the NOFDM systems when a power
and bit allocation algorithm (like the Campello one) is employed in order to satisfy
a certain QoS constrain. A comparison of the performances with OFDM systems is
included.
Finally a simple application of the cognitive radio paradigm employing filterbankbased
multicarrier systems is developed and some interesting results are showed.
File