Full-Diversity QO-STBC Technique for Large-Antenna MIMO Systems

Anoh, Kelvin O.O., Okorafor, G., Adebisi, B., Alabdullah, A., Jones, Steven M.R., Abd-Alhameed, Raed

05 May 2017

Yes / The need to achieve high data rates in modern telecommunication systems, such as 5G standard, motivates the study and development of large antenna and multiple-input multiple-output (MIMO) systems. This study introduces a large antenna-order design of MIMO quasi-orthogonal space-time block code (QO-STBC) system that achieves better signal-to-noise ratio (SNR) and bit-error ratio (BER) performances than the conventional QO-STBCs with the potential for massive MIMO (mMIMO) configurations. Although some earlier MIMO standards were built on orthogonal space-time block codes (O-STBCs), which are limited to two transmit antennas and data rates, the need for higher data rates motivates the exploration of higher antenna configurations using different QO-STBC schemes. The standard QO-STBC offers a higher number of antennas than the O-STBC with the full spatial rate. Unfortunately, also, the standard QO-STBCs are not able to achieve full diversity due to self-interference within their detection matrices; this diminishes the BER performance of the QO-STBC scheme. The detection also involves nonlinear processing, which further complicates the system. To solve these problems, we propose a linear processing design technique (which eliminates the system complexity) for constructing interference-free QO-STBCs and that also achieves full diversity using Hadamard modal matrices with the potential for mMIMO design. Since the modal matrices that orthogonalize QO-STBC are not sparse, our proposal also supports O-STBCs with a well-behaved peak-to-average power ratio (PAPR) and better BER. The results of the proposed QO-STBC outperform other full diversity techniques including Givens-rotation and the eigenvalue decomposition (EVD) techniques by 15 dB for both MIMO and multiple-input single-output (MISO) antenna configurations at 10−3 BER. The proposed interference-free QO-STBC is also implemented for 16×NR and 32×NR MIMO systems, where NR≤2. We demonstrate 8 x 16 and 32 transmit antenna-enabled MIMO systems with the potential for mMIMO design applications with attractive BER and PAPR performance characteristics.

STBC

QO-STBC

MIMO

Hadamrd

Full-diversity

Intersymbol Interference (ISI)-free

Massive MIMO

mMIMO

PAPR

ON SYMBOL TIMING RECOVERY IN ALL-DIGITAL RECEIVERS

Ghrayeb, Ali A.

10 1900

International Telemetering Conference Proceedings / October 27-30, 1997 / Riviera Hotel and Convention Center, Las Vegas, Nevada / Sandia National Laboratories (SNL) currently achieves a bandwidth efficiency (h ) of 0.5 to 1.0 bps/Hz by using traditional modulation schemes, such as, BPSK and QFSK. SNL has an interest in increasing the present bandwidth efficiency by a factor of 4 or higher with the same allocated bandwidth (about 10 MHz). Simulations have shown that 32- QAM trellis-coded modulation (TCM) gives a good bit error rate (BER) performance, and meets the requirements as far as the bandwidth efficiency is concerned. Critical to achieving this is that the receiver be able to achieve timing synchronization. This paper examines a particular timing recovery algorithm for all-digital receivers. Timing synchronization in a digital receiver can be achieved in different ways. One way of achieving this is by interpolating the original sampled sequence to produce another sampled sequence synchronized to the symbol rate or a multiple of the symbol rate. An adaptive sampling conversion algorithm which performs this function was developed by Floyd Gardner in 1993. In the present work, his algorithm was applied to two different modulation schemes, BPSK and 4-ary PAM. The two schemes were simulated in the presence of AWGN and ISI along with Gardner’s algorithm for timing recovery, and a fractionally spaced equalizer (T/2 FSE) for equalization. Simulations show that the algorithm gives good BER performance for BPSK in all the situations, and at different sampling frequencies, but unfortunately poor performance for the 4-ary PAM scheme. This indicates that Gardner’s algorithm for sampling conversion is not suitable for multi-level signaling schemes.

Bandwidth Efficiency

Trellis Coded Modulation

Symbol Timing Recovery

Equalization

Intersymbol Interference (ISI)

Digital Receivers

Adaptive Sampling Conversion

VLSI αρχιτεκτονική χαμηλής κατανάλωσης για συγχρονισμό σε Multi-band UWB ασύρματα δίκτυα

Πούλος, Αθανάσιος

30 July 2007

Η ΒΥΠ διαθέτει αντίτυπο της διατριβής σε έντυπη μορφή στο βιβλιοστάσιο διδακτορικών διατριβών που βρίσκεται στο ισόγειο του κτιρίου της. / Τα ψηφιακά συστήματα UWB (Ultra Wide-Band) παρέχουν τη δυνατότητα ασύρματης μετάδοσης σε πολύ υψηλό ρυθμό. Λόγω του μεγάλου εύρους ζώνης, το κανάλι εισάγει πολλαπλές ανακλάσεις οι οποίες φέρουν μεγάλο ποσοστό της ωφέλιμης ενέργειας του μεταδιδόμενου σήματος. Η ικανότητα του δέκτη για σύλληψη όσο το δυνατόν περισσότερης ωφέλιμης ενέργειας έχει αντίκτυπο στη συνολική απόδοση του συστήματος. Η χρήση της τεχνικής διαμόρφωσης με πολύπλεξη συχνότητας ορθογωνίων φερουσών (OFDM), που στην συγκεκριμένη περίπτωση (UWB) συνδυάζεται με πολυζωνική (Multi-band) μετάδοση, απλοποιεί τη διαχείριση του συνολικού φάσματος συχνοτήτων. Όμως η διαμόρφωση OFDM παρουσιάζει ιδιαίτερη ευαισθησία σε προβλήματα τόσο διασυμβολικής παρεμβολής (ISI) όσο και διακαναλικής παρεμβολής (ICI), λόγω του έντονου διασκορπιστικού χαρακτήρα του καναλιού καθώς επίσης και τυχόν αποκλίσεων που εμφανίζονται στους ταλαντωτές πομπού-δέκτη. Τα παραπάνω επιβάλλουν τη χρήση σύνθετων αλγορίθμων συγχρονισμού και συντονισμού (time and frequency synchronization) μεταξύ πομπού και δέκτη για την ομαλή λειτουργία. Στα πλαίσια της διπλωματικής αυτής θα πραγματοποιηθεί επιλογή κατάλληλων αλγορίθμων για τα προαναφερθέντα προβλήματα, οι οποίοι θα πρέπει να πληρούν τις προδιαγραφές του υπό διαμόρφωση διεθνούς προτύπου 802.15.3α και θα αναπτυχθούν βέλτιστες αρχιτεκτονικές VLSI, με στόχο τόσο το χαμηλό κόστος υλοποίησης όσο και την χαμηλή κατανάλωση ισχύος. / In this project have been studied the low power VLSI architecture for synchronization algorithms in Multi-band UWB Wireless systems. The main issues are timing and frequency synchronization algorithms.

Πολυζωνική μετάδοση

802.15.3α

VLSI

621.382 15

Multi-band transmission

UWB

OFDM

Time synchronization

Frequency synchronization

Intersymbol Interference (ISI)

Intercarrier Interference (ICI)

802.15.3α

VLSI