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Diversidade de antena em redes de sensores sem fio industriais como técnica para aumento da confiabilidadeAraújo, Sandro Roberto de January 2018 (has links)
Este trabalho concentra-se no aumento da robustez à taxa de erros em redes de sensores sem fio industriais (RSSFI). Para alcançar tal objetivo, é preciso, de algum modo, contornar os problemas intrínsecos da comunicação sem fio, que são, o ruído ambiental, interferências e desvanecimento por multipercurso. O multipercurso pode ser considerado um dos principais fatores que tornam as comunicações nas redes de sensores sem fio (RSSF) um verdadeiro desafio quando comparadas com outros meios, como a transmissão em fibra óptica, cabo ou mesmo transmissões de rádio ponto-a-ponto. Nesse sentido, propõe-se a diversidade de antenas como uma solução para minimizar os efeitos do multicaminho, com o objetivo de melhorar a confiabilidade do enlace de rádio para permitir o emprego de RSSF densas. O potencial da diversidade de antenas em RSSF não está totalmente explorado em aplicações industriais. Esta dissertação apresenta ainda, a técnica “Combinação de seleção” para RSSFI através de um algoritmo que seleciona a porta do receptor que apresenta o melhor indicador de qualidade de enlace e realiza a comutação das antenas nos módulos de rádio. Os resultados são analisados para dois tipos de enlaces, isto é, com e sem diversidade de antenas na recepção, e discute-se opções para melhorar o PER (“Packet Error Rate”) com as atuais técnicas de diversidade. / This work concentrates on the increase of reliability and robustness in Industrial Wireless Sensor Networks (IWSNs), decreasing the Packet Error Rate (PER). To achieve this objective, is need to somehow circumvent and reduce the underlying problems of wireless communication, which are: environmental noise, interference, and multipath fading. The multipath can be seen as the main factor which becomes the communications in the Wireless Sensor Networks (WSNs) a real challenge when compared to other types of means such as a transmission in fiber, cable or even point-to-point radio transmissions. In this sense, it is proposed antenna diversity as solution to reduce these effects, with the aim to improve the reliability of the radio link to allow the use of dense WSNs. The potential of antenna diversity in WSN is not fully exploited in industrial applications. In this sense, this dissertation presents the "Combination of selection" technique for IWSNs through an internal algorithm that selects the receiver port that has the highest LQI ("Link Quality Indicator") and performs an antenna switching in the radio modules. Also, options to improve PER using diversity techniques are discussed.
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Error resilient video communications using high level M-QAM : modelling and simulation of a comparative analysis of a dual-priority M-QAM transmission system for H.264/AVC video applications over band-limited and error-phone channelsAbdurrhman, Ahmed B. M. January 2010 (has links)
An experimental investigation of an M level (M = 16, 64 and 256) Quadrature Amplitude Modulation (QAM) transmission system suitable for video transmission is presented. The communication system is based on layered video coding and unequal error protection to make the video bitstream robust to channel errors. An implementation is described in which H.264 video is protected unequally by partitioning the compressed data into two layers of different visual importance. The partition scheme is based on a separation of the group of pictures (GoP) in the intra-coded frame (I-frame) and predictive coded frame (P frame). This partition scheme is then applied to split the H.264-coded video bitstream and is suitable for Constant Bit Rate (CBR) transmission. Unequal error protection is based on uniform and non-uniform M-QAM constellations in conjunction with different scenarios of splitting the transmitted symbol for protection of the more important information of the video data; different constellation arrangements are proposed and evaluated to increase the capacity of the high priority layer. The performance of the transmission system is evaluated under Additive White Gaussian Noise (AWGN) and Rayleigh fading conditions. Simulation results showed that in noisy channels the decoded video can be improved by assigning a larger portion of the video data to the enhancement layer in conjunction with non-uniform constellation arrangements; in better channel conditions the quality of the received video can be improved by assigning more bits in the high priority channel and using uniform constellations. The aforementioned varying conditions can make the video transmission more successful over error-prone channels. Further techniques were developed to combat various channel impairments by considering channel coding methods suitable for layered video coding applications. It is shown that a combination of non-uniform M-QAM and forward error correction (FEC) will yield a better performance. Additionally, antenna diversity techniques are examined and introduced to the transmission system that can offer a significant improvement in the quality of service of mobile video communication systems in environments that can be modelled by a Rayleigh fading channel.
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Επαναληπτική αποκωδικοποίηση χωροχρονικών κωδικών (space-time codes) σε συστήματα ορθογώνιας πολυπλεξίας φερουσών: αναπαράσταση δεδομένων και πολυπλοκότηταΑγγελόπουλος, Aπόστολος 06 August 2007 (has links)
Η χρήση πολλαπλών κεραιών παίζει πλέον ένα πολύ σημαντικό ρόλο στη βελτίωση των ραδιοτηλεπικοινωνιών. Για το λόγο αυτό, ο τομέας των τηλεπικοινωνιακών συστημάτων πολλαπλών κεραιών μετάδοσης – λήψης (συστήματα ΜΙΜΟ) βρίσκεται στο προσκήνιο της ασύρματης έρευνας. Πρόσφατα, αποτελέσματα ερευνών έδειξαν ότι υπάρχει δυνατότητα αύξησης της χωρητικότητας στα ασύρματα τηλεπικοινωνιακά συστήματα χρησιμοποιώντας τεχνικές διαφοροποίησης μεταξύ πομπού – δέκτη (antenna diversity), δηλαδή δημιουργίας πολλαπλών ανεξάρτητων καναλιών ανάμεσα τους.
Στην παρούσα εργασία μελετούνται τεχνικές κωδικοποίησης που εκμεταλλεύονται τη χωρική διαφοροποίηση κάνοντας χρήση χωροχρονικών κωδικών (space – time coding). Η μελέτη εστιάζεται στη χρήση χωροχρονικών κωδικών ανά μπλοκ από την πλευρά του πομπού, εξαιτίας της απλότητας υλοποίησης τους καθώς και της ικανότητας υποστήριξης πολλαπλών κεραιών από τη πλευρά του σταθμού βάσης. Η ανάλυσή τους γίνεται με βάση την εφαρμογή τους σε συστήματα που χρησιμοποιούν διαμόρφωση με πολυπλεξία ορθογώνιων φερουσών (OFDM). Η διαμόρφωση αυτή επιλέχθηκε γιατί υποστηρίζει υψηλούς ρυθμούς δεδομένων στα ασύρματα συστήματα και δείχνει άριστη συμπεριφορά σε κανάλια με επιλεκτική παραμόρφωση στη συχνότητα.
Στη συνέχεια μελετώνται αλγόριθμοι επαναληπτικής αποκωδικοποίησης, δίνοντας έμφαση σε ένα ευρέως διαδεδομένο αλγόριθμο, τον Μέγιστο εκ των Υστέρων (MAP). Αναλύονται διεξοδικά τα βήματα του, καθώς και διάφορες τροποποιήσεις – βελτιστοποιήσεις του. Οι επαναληπτικοί αλγόριθμοι αποκωδικοποίησης αποτελούν πλέον ένα πολύ ισχυρό εργαλείο για την αποκωδικοποίηση Forward Error Correction κωδικοποιήσεων με χρήση συνελικτικών κωδικών, προσδίδοντας στα συστήματα αποδόσεις κοντά στο όριο του Shannon.
Τέλος, πραγματοποιούνται κατάλληλες υλοποιήσεις που προέκυψαν από το συνδυασμό των εν λόγω αλγορίθμων επαναληπτικής αποκωδικοποίησης με τους χωροχρονικούς κώδικες ανά μπλοκ πάνω σε ένα σύστημα κεραιών με χρήση OFDM. Γίνεται σύγκριση της απόδοσης των συστημάτων αυτών με βάση την αντίστοιχη υλοποίηση του εκάστοτε αλγορίθμου επαναληπτικής αποκωδικοποίησης και μελετούνται σε βάθος διάφορες τροποποιήσεις που μπορούν δεχθούν με κριτήριο τη χαμηλή πολυπλοκότητα υλοποίησης. Για την αξιολόγηση της απόδοσης, γίνεται μία περαιτέρω σύγκριση με χρήση αναπαράστασης σταθερής υποδιαστολής και εξάγονται σειρά συμπερασμάτων από τις πειραματικές μετρήσεις που προέκυψαν. / The use of multiple antennas is an essential issue in telecommunications, nowadays. So, multiple input – multiple output systems (MIMO) has attracted a lot of attention in wireless research. Lately, it has been shown that it can be an improvement in the capacity of wireless communication systems by using antenna diversity, that’s different independent channels between transmitter and receiver.
In this thesis, we study coding techniques that exploit space diversity by using space – time codes. Particularly, we focus on space – time block coding (STBC) from the transmitter’s point of view, because of the simplicity of its implementation and the ability to support multiple antennas at the base stations. The analysis is based on the systems that use Orthogonal Frequency Division Multiplexing Systems (OFDM). This technique was chosen because it can support high data rates and it behaves very well in a frequency selective fading channel.
Moreover, we study iterative decoding algorithms and we focus on a very well known algorithm, the Maximum A Posteriori (MAP). There, we analyze its steps and its modifications and improvements. The iterative decoding algorithms are a cornerstone on decoding Forward Error Correction codes, such as Convolutional codes, almost reaching the Shannon limit.
Finally, there are different kinds of implementations using suitable iterative decoding algorithms in concatenation with space – time block coding with antennas and ODFM. We compare the performance of the corresponding systems and investigate the complexity trying to maintain it in a low level. For a thorough investigation, we also use fixed point arithmetic in these implementations.
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Error relilient video communications using high level M-QAM. Modelling and simulation of a comparative analysis of a dual-priority M-QAM transmission system for H.264/AVC video applications over band-limited and error-phone channels.Abdurrhman, Ahmed B.M. January 2010 (has links)
An experimental investigation of an M level (M = 16, 64 and 256) Quadrature Amplitude Modulation (QAM) transmission system suitable for video transmission is presented. The communication system is based on layered video coding and unequal error protection to make the video bitstream robust to channel errors. An implementation is described in which H.264 video is protected unequally by partitioning the compressed data into two layers of different visual importance. The partition scheme is based on a separation of the group of pictures (GoP) in the intra-coded frame (I-frame) and predictive coded frame (P frame). This partition scheme is then applied to split the H.264-coded video bitstream and is suitable for Constant Bit Rate (CBR) transmission. Unequal error protection is based on uniform and non-uniform M-QAM constellations in conjunction with different scenarios of splitting the transmitted symbol for protection of the more important information of the video data; different constellation arrangements are proposed and evaluated to increase the capacity of the high priority layer. The performance of the transmission system is evaluated under Additive White Gaussian Noise (AWGN) and Rayleigh fading conditions.
Simulation results showed that in noisy channels the decoded video can be improved by assigning a larger portion of the video data to the enhancement layer in conjunction with non-uniform constellation arrangements; in better channel conditions the quality of the received video can be improved by assigning more bits in the high priority channel and using uniform constellations. The aforementioned varying conditions can make the video transmission more successful over error-prone channels. Further techniques were developed to combat various channel impairments by considering channel coding methods suitable for layered video coding applications. It is shown that a combination of non-uniform M-QAM and forward error correction (FEC) will yield a better performance. Additionally, antenna diversity techniques are examined and introduced to the transmission system that can offer a significant improvement in the quality of service of mobile video communication systems in environments that can be modelled by a Rayleigh fading channel.
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Channel Probing for an Indoor Wireless Communications ChannelHunter, Brandon 13 March 2003 (has links) (PDF)
The statistics of the amplitude, time and angle of arrival of multipaths in an indoor environment are all necessary components of multipath models used to simulate the performance of spatial diversity in receive antenna configurations. The model presented by Saleh and Valenzuela, was added to by Spencer et. al., and included all three of these parameters for a 7 GHz channel. A system was built to measure these multipath parameters at 2.4 GHz for multiple locations in an indoor environment. Another system was built to measure the angle of transmission for a 6 GHz channel. The addition of this parameter allows spatial diversity at the transmitter along with the receiver to be simulated. The process of going from raw measurement data to discrete arrivals and then to clustered arrivals is analyzed. Many possible errors associated with discrete arrival processing are discussed along with possible solutions. Four clustering methods are compared and their relative strengths and weaknesses are pointed out. The effects that errors in the clustering process have on parameter estimation and model performance are also simulated.
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