113 research outputs found
A Novel Construction of Multi-group Decodable Space-Time Block Codes
Complex Orthogonal Design (COD) codes are known to have the lowest detection
complexity among Space-Time Block Codes (STBCs). However, the rate of square
COD codes decreases exponentially with the number of transmit antennas. The
Quasi-Orthogonal Design (QOD) codes emerged to provide a compromise between
rate and complexity as they offer higher rates compared to COD codes at the
expense of an increase of decoding complexity through partially relaxing the
orthogonality conditions. The QOD codes were then generalized with the so
called g-symbol and g-group decodable STBCs where the number of orthogonal
groups of symbols is no longer restricted to two as in the QOD case. However,
the adopted approach for the construction of such codes is based on sufficient
but not necessary conditions which may limit the achievable rates for any
number of orthogonal groups. In this paper, we limit ourselves to the case of
Unitary Weight (UW)-g-group decodable STBCs for 2^a transmit antennas where the
weight matrices are required to be single thread matrices with non-zero entries
in {1,-1,j,-j} and address the problem of finding the highest achievable rate
for any number of orthogonal groups. This special type of weight matrices
guarantees full symbol-wise diversity and subsumes a wide range of existing
codes in the literature. We show that in this case an exhaustive search can be
applied to find the maximum achievable rates for UW-g-group decodable STBCs
with g>1. For this purpose, we extend our previously proposed approach for
constructing UW-2-group decodable STBCs based on necessary and sufficient
conditions to the case of UW-g-group decodable STBCs in a recursive manner.Comment: 12 pages, and 5 tables, accepted for publication in IEEE transactions
on communication
A New Low-Complexity Decodable Rate-5/4 STBC for Four Transmit Antennas with Nonvanishing Determinants
The use of Space-Time Block Codes (STBCs) increases significantly the optimal
detection complexity at the receiver unless the low-complexity decodability
property is taken into consideration in the STBC design. In this paper we
propose a new low-complexity decodable rate-5/4 full-diversity 4 x 4 STBC. We
provide an analytical proof that the proposed code has the
Non-Vanishing-Determinant (NVD) property, a property that can be exploited
through the use of adaptive modulation which changes the transmission rate
according to the wireless channel quality. We compare the proposed code to the
best existing low-complexity decodable rate-5/4 full-diversity 4 x 4 STBC in
terms of performance over quasi-static Rayleigh fading channels, worst- case
complexity, average complexity, and Peak-to-Average Power Ratio (PAPR). Our
code is found to provide better performance, lower average decoding complexity,
and lower PAPR at the expense of a slight increase in worst-case decoding
complexity.Comment: 5 pages, 2 figures and 1 table; IEEE Global Telecommunications
Conference (GLOBECOM 2011), 201
A New Low-Complexity Decodable Rate-1 Full-Diversity 4 x 4 STBC with Nonvanishing Determinants
Space-time coding techniques have become common-place in wireless
communication standards as they provide an effective way to mitigate the fading
phenomena inherent in wireless channels. However, the use of Space-Time Block
Codes (STBCs) increases significantly the optimal detection complexity at the
receiver unless the low complexity decodability property is taken into
consideration in the STBC design. In this letter we propose a new
low-complexity decodable rate-1 full-diversity 4 x 4 STBC. We provide an
analytical proof that the proposed code has the Non-Vanishing-Determinant (NVD)
property, a property that can be exploited through the use of adaptive
modulation which changes the transmission rate according to the wireless
channel quality. We compare the proposed code to existing low-complexity
decodable rate-1 full-diversity 4 x 4 STBCs in terms of performance over
quasi-static Rayleigh fading channels, detection complexity and Peak-to-Average
Power Ratio (PAPR). Our code is found to provide the best performance and the
smallest PAPR which is that of the used QAM constellation at the expense of a
slight increase in detection complexity w.r.t. certain previous codes but this
will only penalize the proposed code for high-order QAM constellations.Comment: 5 pages, 3 figures, and 1 table; IEEE Transactions on Wireless
Communications, Vol. 10, No. 8, AUGUST 201
A New Family of Low-Complexity Decodable STBCs for Four Transmit Antennas
In this paper we propose a new construction method for rate-1
Fast-Group-Decodable (FGD) Space-Time-Block Codes (STBC)s for 2^a transmit
antennas. We focus on the case of a=2 and we show that the new FGD rate-1 code
has the lowest worst-case decoding complexity among existing comparable STBCs.
The coding gain of the new rate-1 code is then optimized through constellation
stretching and proved to be constant irrespective of the underlying QAM
constellation prior to normalization. In a second step, we propose a new rate-2
STBC that multiplexes two of our rate-1 codes by the means of a unitary matrix.
A compromise between rate and complexity is then obtained through puncturing
our rate-2 code giving rise to a new rate-3/2 code. The proposed codes are
compared to existing codes in the literature and simulation results show that
our rate-3/2 code has a lower average decoding complexity while our rate-2 code
maintains its lower average decoding complexity in the low SNR region at the
expense of a small performance loss.Comment: 5 pages, 4 figures and 1 table. Accepted for publication in IEEE
International Conference on Communications (ICC 2012), 201
A New Criterion to Jointly Design the Antenna and Optimize the Communication Capacity in IR-UWB.
International audienceThis paper presents the impact of the antenna design over the capacity of a IR-UWB system in a Multi-User Interference environment. A new antenna design is proposed and it is showed using a new performance criterion that for this design, the communication capacity given by the Sholtz's pulse [13] might be reached using some other types of pulses
Performance evaluation of non-prefiltering vs. time reversal prefiltering in distributed and uncoordinated IR-UWB ad-hoc networks
Time Reversal (TR) is a prefiltering scheme mostly analyzed in the context of centralized and synchronous IR-UWB networks, in order to leverage the trade-off between communication performance and device complexity, in particular in presence of multiuser interference. Several strong assumptions have been typically adopted in the analysis of TR, such as the absence of Inter-Symbol / Inter-Frame Interference (ISI/IFI) and multipath dispersion due to complex signal propagation. This work has the main goal of comparing the performance of TR-based systems with traditional non-prefiltered schemes, in the novel context of a distributed and uncoordinated IR-UWB network, under more realistic assumptions including the presence of ISI/IFI and multipath dispersion. Results show that, lack of power control and imperfect channel knowledge affect the performance of both non-prefiltered and TR systems; in these conditions, TR prefiltering still guarantees a performance improvement in sparse/low-loaded and overloaded network scenarios, while the opposite is true for less extreme scenarios, calling for the developement of an adaptive scheme that enables/disables TR prefiltering depending on network conditions
Quasi-continuous waveform design for dynamic range reduction
International audienceA study of quasi-continuous waveform (QCW) and its performance in detection is presented taking into consideration eclipsing loss and free space decay. Genetic algorithm is then used to optimise the waveform and lower the dynamic range of the matched filtering output. The resulting waveform with high duty cycle and minimal loss at maximal range maintains good detection performance along the whole operating range of the radar
Une approche cognitive des systèmes de communication UWB-IR
Dans le contexte émergeant de coexistence des systèmes de communication sans fil, nous étudions et analysons la possibilité d'adaptation de la transmission et des paramètres du réseau aux changements imprévisibles de l'environnement radio. Le paradigme de la radio cognitive est appliqué aux systèmes UWB en adaptant les paramètres du signal et en adoptant une procédure de contrôle d'admission basée sur la perception de l'environnement radio, l'aspect particulier des interférences lors de la réception des signaux UWB-IR est pris en compte. Nous montrons que des résultats significatifs sont obtenus en termes d'efficacité énergétique du réseau grâce à l'introduction de mécanismes cognitifs dans le contexte des systèmes sans fil IEEE 802.15.4a
Trade-off Between the Number of Fingers in the Prefilter and in the Rake Receiver in Time Reversal IR-UWB
Abstract-In this paper we investigate the trade-off between the number of fingers in the prefilter of a TR-IR-UWB system versus the number of fingers in the rake receiver. This allows studying the gain brought by time reversal when the complexity is switched from the receiver to the transmitter i.e. when the number of fingers is increased in the prefilter, while it is reduced in the rake receiver
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