Development and Testing of A Space-borne GPS Signal Strength Sensor

Lu, Dianhong

13 October 2003

The Global Positioning System (GPS) satellite signals provide not only traditional radionavigation service but inexpensive and convenient radio beacons for signal propagation studies on ionosphere and atmosphere. This thesis describes the development and testing of a specialized GPS sensor which measures, plots and records real-time high-resolution L1 (1575.42MHz) GPS signal strength at a data rate of up to 10Hz. The instrument is based on an open architecture GPS receiver development kit that can be modified and rebuilt. The signal strength is defined as mean-square signal strength in the thesis. The coarse/acquisition code (C/A-code) correlation is applied and the raw correlation data from a GPS correlator chip is obtained to calculate the signal strength. The gain variation of the automatic gain control (AGC) in the GPS signal link is considered, and a model is designed and implemented in data post-processing to reduce the AGC distortion to GPS signal strength measurements. Speed limitation of 1,000 knots and height limitation of 60,000 feet are removed so that it can track spacecraft such as low earth orbit (LEO) satellite. Four testing plans are developed and conducted to test the GPS signal strength sensor. A GPS simulator is used and the testing results prove that the space-borne sensor is fully operational and the signal strength resolution can be smaller than 0.05dB. Additionally, a COM-port-to-TCP/IP GPS simulation remote control gateway is designed and implemented for the senor and the GPS simulator to conduct formation flying. A graphic user interface (GUI) program is also built to retrieve data from a commercial high-performance space-borne GPS receiver for comparison. A Red Hat Linux signal strength sensor based on the National Aeronautics and Space Administration (NASA) PiVoT GPS receiver is achieved by modifications. The NASA PiVoT sensor, working together with the former signal strength sensor and the commercial space-borne GPS receiver, will strengthen our academic research strength in the studies on the ionospheric and atmospheric effects and irregularities which cause GPS signal degradation and scintillations. / Master of Science

Linux PiVoT

DS-CDMA

GPS Builder

GP2021

GPS simulator

GP2015

Spacecraft tracking

Ashtech G12

Remote control task

COMPORT

GPS signal strength sensor

An assessment of the GPS L5 signal based on multiple vendor receivers

Smyers, Serena Ashley

21 February 2012

The L5 signal of the Global Positioning System (GPS) is becoming available on an increasing number of Block IIF satellites. As the third civilian signal, L5 is superior in signal design to the L1 C/A and L2C civilian signals. This new signal has been marked healthy for use on selected satellites since 2010, yet the hardware capable of tracking the L5 signal is still in the early stages of development. This work investigates the characteristics of the new signal and the quality of data produced by L5-tracking receivers. Commonly used receiver models chosen for this study are the Leica GRX1200+GNSS, the Trimble NetR8, and the Javad Delta TRE-G3TH. The metrics used in this analysis to assess the quality of data produced by these receivers are signal strength, receiver phase noise, receiver code noise, and multipath. The data used in these analyses were obtained from the International GNSS Service for the days of the year 275 to 281 in 2011. Metrics averaged over the GPS week 1656 provide a good indication of the overall performance of the receivers. / text

GPS

L5

Triple-frequency

GPS modernization

GPS receiver

Signal strength

Carrier to noise

Multipath

Code multipath

Code noise

Phase noise

Receiver noise

Block IIF

Ionosphere

Carrier phase

Pseudorange

IGS

CDDIS

SOPAC

NOAA

CORS

Javad

Trimble

Leica

Antenna

Gain

Tracking loop

Αλγοριθμικές τεχνικές εντοπισμού και παρακολούθησης πολλαπλών πηγών από ασύρματα δίκτυα αισθητήρων

Αμπελιώτης, Δημήτριος

12 April 2010

Οι πρόσφατες εξελίξεις στις ασύρματες επικοινωνίες και στα ηλεκτρονικά κυκλώματα έχουν επιτρέψει την ανάπτυξη υπολογιστικών διατάξεων χαμηλού κόστους και χαμηλής κατανάλωσης ισχύος, οι οποίες ενσωματώνουν δυνατότητες μέτρησης (sensing), επεξεργασίας και ασύρματης επικοινωνίας. Οι διατάξεις αυτές, οι οποίες έχουν ιδιαίτερα μικρό μέγεθος, καλούνται κόμβοι αισθητήρες. Ένα ασύρματο δίκτυο κόμβων αισθητήρων αποτελείται από ένα πλήθος κόμβων οι οποίοι έχουν αναπτυχθεί σε κάποια περιοχή ενδιαφέροντος προκειμένου να μετρούν κάποια μεταβλητή του περιβάλλοντος. Ανάμεσα σε πολλές εφαρμογές, ο εντοπισμός και η παρακολούθηση των θέσεων πηγών οι οποίες εκπέμπουν κάποιο σήμα (π.χ. ακουστικό, ηλεκτρομαγνητικό) αποτελεί ένα πολύ ενδιαφέρον θέμα, το οποίο μάλιστα μπορεί να χρησιμοποιηθεί και ως βάση για τη μελέτη άλλων προβλημάτων τα οποία εμφανίζονται στα ασύρματα δίκτυα αισθητήρων. Οι περισσότερες από τις υπάρχουσες τεχνικές εντοπισμού θέσης μιας πηγής από μια συστοιχία αισθητήρων μπορούν να ταξινομηθούν σε δυο κατηγορίες: (α) Τις τεχνικές οι οποίες χρησιμοποιούν μετρήσεις διεύθυνσης άφιξης (Direction of Arrival, DOA) και (β) τις τεχνικές οι οποίες χρησιμοποιούν μετρήσεις διαφοράς χρόνων άφιξης (Time Difference of Arrival, TDOA). Ωστόσο, οι τεχνικές αυτές απαιτούν υψηλό ρυθμό δειγματοληψίας και ακριβή συγχρονισμό των κόμβων και δε συνάδουν έτσι με τις περιορισμένες ικανότητες των κόμβων αισθητήρων. Για τους λόγους αυτούς, το ενδιαφέρον έχει στραφεί σε μια τρίτη κατηγορία τεχνικών οι οποίες χρησιμοποιούν μετρήσεις ισχύος (Received Signal Strength, RSS). Το πρόβλημα του εντοπισμού θέσης χρησιμοποιώντας μετρήσεις ισχύος είναι ένα πρόβλημα εκτίμησης, όπου οι μετρήσεις συνδέονται με τις προς εκτίμηση παραμέτρους με μη-γραμμικό τρόπο. Στα πλαίσια της Διδακτορικής Διατριβής ασχολούμαστε αρχικά με την περίπτωση όπου επιθυμούμε να εκτιμήσουμε τη θέση και την ισχύ μιας πηγής χρησιμοποιώντας μετρήσεις ισχύος οι οποίες φθίνουν με βάση το αντίστροφο του τετραγώνου της απόστασης ανάμεσα στην πηγή και το σημείο μέτρησης. Για το πρόβλημα αυτό, προτείνουμε έναν εκτιμητή ο οποίος δίνει τις παραμέτρους της πηγής ως λύση ενός γραμμικού προβλήματος ελαχίστων τετραγώνων. Στη συνέχεια, υπολογίζουμε κατάλληλα βάρη και προτείνουμε έναν εκτιμητή ο οποίος δίνει τις παραμέτρους της πηγής ως λύση ενός προβλήματος ελαχίστων τετραγώνων με βάρη. Ακόμα, τροποποιούμε κατάλληλα τον τελευταίο εκτιμητή έτσι ώστε να είναι δυνατή η κατανεμημένη υλοποίησή του μέσω των προσαρμοστικών αλγορίθμων Least Mean Square (LMS) και Recursive Least Squares (RLS). Στη συνέχεια, εξετάζουμε την περίπτωση όπου ενδιαφερόμαστε να εκτιμήσουμε τη θέση μιας πηγής αλλά δεν έχουμε καμιά πληροφορία σχετικά με το μοντέλο εξασθένισης της ισχύος. Έτσι, υποθέτουμε πως αυτό περιγράφεται από μια άγνωστη γνησίως φθίνουσα συνάρτηση της απόστασης. Αρχικά, προσεγγίζουμε το πρόβλημα εκτίμησης κάνοντας την υπόθεση πως οι θέσεις των κόμβων αποτελούν τυχαία σημεία ομοιόμορφα κατανεμημένα στο επίπεδο. Χρησιμοποιώντας την υπόθεση αυτή, υπολογίζουμε εκτιμήσεις για τις αποστάσεις ανάμεσα στους κόμβους και την πηγή, και αναπτύσσουμε έναν αλγόριθμο εκτίμησης της θέσης της πηγής. Στη συνέχεια, προσεγγίζουμε το πρόβλημα εκτίμησης χωρίς την υπόθεση περί ομοιόμορφης κατανομής των θέσεων των κόμβων στο επίπεδο. Προτείνουμε μια κατάλληλη συνάρτηση κόστους για την περίπτωση αυτή, και δείχνουμε την ύπαρξη μιας συνθήκης υπό την οποία η βέλτιστη λύση μπορεί να υπολογιστεί. Η λύση αυτή είναι εσωτερικό σημείο ενός κυρτού πολυγώνου, το οποίο ονομάζουμε ταξινομημένο τάξης-K κελί Voronoi. Έτσι, δίνουμε αλγορίθμους υπολογισμού της λύσης αυτής, καθώς και κατανεμημένους αλγορίθμους οι οποίοι βασίζονται σε προβολές σε κυρτά σύνολα. Ακόμα, ασχολούμαστε με τις ιδιότητες των κελιών αυτών στην περίπτωση όπου οι θέσεις των κόμβων αισθητήρων είναι ομοιόμορφα κατανεμημένες στο επίπεδο και υπολογίζουμε κάποια φράγματα για το εμβαδόν τους. Τέλος, ασχολούμαστε με την περίπτωση όπου ενδιαφερόμαστε να εκτιμήσουμε τις θέσεις πολλαπλών πηγών με γνωστό μοντέλο εξασθένισης της ισχύος. Για το πρόβλημα αυτό, αρχικά προτείνουμε έναν αλγόριθμο διαδοχικής εκτίμησης και ακύρωσης της συνεισφοράς κάθε πηγής, προκειμένου να υπολογιστούν σταδιακά οι θέσεις όλων των πηγών. Ο αλγόριθμος αυτός, αποτελείται από τρία βήματα κατά τα οποία πρώτα υπολογίζεται μια προσεγγιστική θέση για την πηγή, στη συνέχεια εκτιμάται ένα σύνολο κόμβων το οποίο δέχεται μικρής έντασης παρεμβολή από τις υπόλοιπες πηγές, και τέλος επιχειρείται μια λεπτομερέστερη εκτίμηση της θέσης κάθε πηγής. Στη συνέχεια, επεκτείνοντας την τεχνική αυτή, προτείνουμε έναν επαναληπτικό αλγόριθμο εκτίμησης ο οποίος βασίζεται στον αλγόριθμο εναλλασσόμενων προβολών (Alternating Projections). Εξετάζουμε επίσης μεθόδους οι οποίες οδηγούν στη μείωση της υπολογιστικής πολυπλοκότητας του αλγορίθμου αυτού. / Technology advances in microelectronics and wireless communications have enabled the development of small-scale devices that integrate sensing, processing and short-range radio capabilities. The deployment of a large number of such devices, referred to as sensor nodes, over a territory of interest, defines the so-called wireless sensor network. Wireless sensor networks have attracted considerable attention in recent years and have motivated many new challenges, most of which require the synergy of many disciplines, including signal processing, networking and distributed algorithms. Among many other applications, source localization and tracking has been widely viewed as a canonical problem of wireless sensor networks. Furthermore, it constitutes an easily perceived problem that can be used as a vehicle to study more involved information processing and organization problems. Most of the source localization methods that have appeared in the literature can be classified into two broad categories, according to the physical variable they utilize. The algorithms of the first category utilize “time delay of arrival”(TDOA) measurements, and the algorithms of the second category use “direction of arrival” (DOA) measurements. DOA estimates are particularly useful for locating sources emitting narrowband signals, while TDOA measurements offer the increased capability of localizing sources emitting broadband signals. However, the methods of both categories impose two major requirements that render them inappropriate to be used in wireless sensor networks: (a) the analog signals at the outputs of the spatially distributed sensors should be sampled in a synchronized fashion, and (b) the sampling rate used should be high enough so as to capture the features of interest. These requirements, in turn, imply that accurate distributed synchronization methods should be implemented so as to keep the remote sensor nodes synchronized and that high frequency electronics as well as increased bandwidth are needed to transmit the acquired measurements. Due to the aforementioned limitations, source localization methods that rely upon received signal strength (RSS) measurements - originally explored for locating electromagnetic sources - have recently received revived attention. In this Thesis, we begin our study by considering the localization of an isotropic acoustic source using energy measurements from distributed sensors, in the case where the energy decays according to an inverse square law with respect to the distance. While most acoustic source localization algorithms require that distance estimates between the sensors and the source of interest are available, we propose a linear least squares criterion that does not make such an assumption. The new criterion can yield the location of the source and its transmit power in closed form. A weighted least squares cost function is also considered, and distributed implementation of the proposed estimators is studied. Numerical results indicate significant performance improvement as compared to a linear least squares based approach that utilizes energy ratios, and comparable performance to other estimators of higher computational complexity. In the sequel, we turn our attention to the case where the energy decay model is not known. For solving the localization problem in this case, we first make the assumption that the locations of the nodes near the source can be well described by a uniform distribution. Using this assumption, we derive distance estimates that are independent of both the energy decay model and the transmit power of the source. Numerical results show that these estimates lead to improved localization accuracy as compared to other model-independent approaches. In the sequel, we consider the more general case where the assumption about the uniform deployment of the sensors is not required. For this case, an optimization problem that does not require knowledge of the underlying energy decay model is proposed, and a condition under which the optimal solution can be computed is given. This condition employs a new geometric construct, called the sorted order-K Voronoi diagram. We give centralized and distributed algorithms for source localization in this setting. Finally, analytical results and simulations are used to verify the performance of the developed algorithms. The next problem we consider is the estimation of the locations of multiple acoustic sources by a network of distributed energy measuring sensors. The maximum likelihood (ML) solution to this problem is related to the optimization of a non-convex function of, usually, many variables. Thus, search-based methods of high complexity are required in order to yield an accurate solution. In order to reduce the computational complexity of the multiple source localization problem, we propose two methods. The first method proposes a sequential estimation algorithm, in which each source is localized, its contribution is cancelled, and the next source is considered. The second method makes use of an alternating projection (AP) algorithm that decomposes the original problem into a number of simpler, yet also non-convex, optimization steps. The particular form of the derived cost functions of each such optimization step indicates that, in some cases, an approximate form of these cost functions can be used. These approximate cost functions can be evaluated using considerably lower computational complexity. Thus, a low-complexity version of the AP algorithm is proposed. Extensive simulation results demonstrate that the proposed algorithm offers a performance close to that of the exact AP implementation, and in some cases, similar performance to that of the ML estimator.

Μετρήσεις ισχύος

Θεωρία εκτίμησης

Διαγράμματα voronoi

621.382 2

Wireless sensor networks

Source localization

Received signal strength

Estimation theory

Voronoi diagrams

Projections onto convex sets

RF signal modeling and deployment strategy targeting outdoor RSS-based localization and tracking applications in wireless sensor network / Μοντελοποίηση μετάδοσης ράδιο-σημάτων και στρατηγική ανάπτυξης ασύρματων δικτύων αισθητήρων εξωτερικού χώρου με στόχο τον εντοπισμό και ιχνηλάτηση μέσω του λαμβανομένου ράδιο-σήματος

Stoyanova, Tsenka

14 May 2012

The localization of the sensor nodes is a fundamental issue in the area of wireless sensor networks (WSNs). An attractive way for estimating the location of mobile or static wireless objects is by using the received signal strength (RSS) attenuation with the distance, which does not require any additional hardware. This is possible due to the fact that in most sensor nodes radios the received signal strength indicator (RSSI) is a standard feature and can be obtained automatically by the received messages. On the other hand the RSS is known for being noisy, unstable, variable and difficult to use in practice. For achieving a better understanding of the nature of these difficulties and limitations, and for identifying the range of applicability of the RSS in localization and tracking scenarios, a thorough study about the RSS and its dependence on the various factors and environmental conditions is essential. The present doctoral dissertation investigates the feasibility of sensor node localization and target tracking with the resources of the WSN technology, when using only the RSS of the exchanged messages. Moreover, it offers experimental support to the hypothesis that proper modeling of the RSS behavior and appropriate selection of the topology parameters are essential for the applicability of WSN in real world conditions. In brief, the present doctoral dissertation concerns with: (i) identifying the main factors that influence the accuracy, the variability and the reliability of the obtained RSS, (ii) modeling the RF signal propagation in the context of WSNs, and (iii)defining the basic deployment constraints and evaluation of the topology parameters that can guarantee successful localization and tracking. For assessing the practical value of various RF-models, experiments using Tmote Sky and TelosB sensor nodes in real-field outdoor environment were carried out. The impact of a number of factors, such as the operating frequency of the radio, the transmitter–receiver distance, the variation of transceivers hardware due to manufacturing tolerances, the antenna orientation, and the environmental conditions, on the RSS was investigated. The influence of the various factors that affect the RF signal propagation and some constraints imposed by the WSN nature was accounted in order to design practical models, suitable for outdoor unobstructed and outdoor tree-obstructed environments. A pre-deployment simulation framework has been introduced and in its context a RF signal propagation-based connectivity strategy (RFCS) has been developed to fulfill three deployment provisions: (i) discovering the most appropriate height from the ground and distances for the sensor nodes, (ii) reducing the transmission power, and (iii) minimizing the interference from non-neighbor nodes. The RFCS uses a RF signal propagation model to predict the RSS in order to identify the most appropriate communication-based deployment parameters, i.e. T-R distance, height from the ground and transmission power. The localization and tracking considerations, by means of localization and tracking techniques, topology parameters and factors influencing the localization and tracking accuracy, are combined in illustrative simulation examples to evaluate their significance concerning the performance of the localization and tracking task. Furthermore, the propagation model and the topology parameters being identified were validated in real outdoor sensor node localization and target tracking tests. / -

Wireless sensor networks

Received signal strength

Localization

Target tracking

RF signal propagation modeling

Deployment

621.384

Εντοπισμός θέσης

Ιχνηλάτηση

Τοποθέτηση

Mecanismo de controle de potência para estimativa de etiquetas em redes de identificação por rádio frequência

Lucena Filho, Walfredo da Costa

03 August 2015

Submitted by Geyciane Santos (geyciane_thamires@hotmail.com) on 2015-11-23T21:24:44Z No. of bitstreams: 1 Dissertação - Walfredo da Costa Lucena Filho.pdf: 2083187 bytes, checksum: 72f63311dba60bbea7ef2d5cc474c601 (MD5) / Approved for entry into archive by Divisão de Documentação/BC Biblioteca Central (ddbc@ufam.edu.br) on 2015-11-30T19:51:08Z (GMT) No. of bitstreams: 1 Dissertação - Walfredo da Costa Lucena Filho.pdf: 2083187 bytes, checksum: 72f63311dba60bbea7ef2d5cc474c601 (MD5) / Approved for entry into archive by Divisão de Documentação/BC Biblioteca Central (ddbc@ufam.edu.br) on 2015-11-30T19:55:39Z (GMT) No. of bitstreams: 1 Dissertação - Walfredo da Costa Lucena Filho.pdf: 2083187 bytes, checksum: 72f63311dba60bbea7ef2d5cc474c601 (MD5) / Made available in DSpace on 2015-11-30T19:55:40Z (GMT). No. of bitstreams: 1 Dissertação - Walfredo da Costa Lucena Filho.pdf: 2083187 bytes, checksum: 72f63311dba60bbea7ef2d5cc474c601 (MD5) Previous issue date: 2015-08-03 / FAPEAM - Fundação de Amparo à Pesquisa do Estado do Amazonas / An RFID system is typically composed of a reader and a set of tags. An anti-collision algorithm is necessary to avoid collision between tags that respond simultaneously to a reader. The most widely used anti-collision algorithm is DFSA (Dynamic Framed Slotted ALOHA) due to its simplicity and low computational cost. In DFSA algorithms, the optimal TDMA (Time Division Multiple Access) frame size must be equal to the number of unread tags. If the exact number of tags is unknown, the DFSA algorithm needs a tag estimator to get closer to the optimal performance. Currently, applications have required the identification of large numbers of tags, which causes an increase in collisions and hence the degradation in performance of the traditional algorithms DFSA. This work proposes a power control mechanism to estimate the number of tags for radio frequency identification networks (RFID). The mechanism divides the interrogation zone into subgroups of tags and then RSSI (Received Signal Strength Indicator) measurements estimate the number of tags in a subarea. The mechanism is simulated and evaluated using a simulator developed in C/C++ language. In this study, we compare the number of slots and identification time, with ideal DFSA algorithm and Q algorithm EPCglobal standard. Simulation results shows the proposed mechanism provides 99% performance of ideal DFSA in dense networks, where there are many tags. Regarding the Q algorithm, we can see the improvement in performance of 6.5%. It is also important to highlight the lower energy consumption of the reader comparing to ideal DFSA is 63%. / Um sistema de identificação por rádio frequência (RFID) é composto basicamente de um leitor e etiquetas. Para que o processo de identificação das etiquetas seja bem sucedido, é necessário um algoritmo anticolisão a fim de evitar colisões entre etiquetas que respondem simultaneamente à interrogação do leitor. O algoritmo anticolisão mais usado é o DFSA (Dynamic Framed Slotted ALOHA) devido à sua simplicidade e baixo custo computacional. Em algoritmos probabilísticos, tal como o DFSA, o tamanho ótimo do quadro TDMA (Time Division Multiple Access) utilizado para leitura das etiquetas deve ser igual à quantidade de etiquetas não lidas. Uma vez que no processo de leitura, normalmente não se sabe a quantidade exata de etiquetas, o algoritmo DFSA faz uso de um estimador para obter um desempenho mais próximo do ideal. Atualmente, as aplicações têm demandado a identificação de grandes quantidades de etiquetas, o que ocasiona um aumento das colisões e, consequentemente, a degradação no desempenho dos algoritmos DFSA tradicionais. Este trabalho propõe um mecanismo de controle de potência para estimar a quantidade de etiquetas em redes de identificação por rádio frequência (RFID). O mecanismo baseia-se na divisão da área de interrogação em subáreas e, consequentemente, subgrupos de etiquetas. Tal divisão é utilizada para realizar medições de RSSI (Received Signal Strength Indicator) e, assim, estimar a quantidade de etiquetas por subárea. O mecanismo é simulado e avaliado utilizando um simulador próprio desenvolvido em linguagem C/C++. Neste estudo, comparam-se os resultados de quantidade de slots e tempo de identificação das etiquetas, com os obtidos a partir da utilização dos algoritmos DFSA ideal e algoritmo padrão Q da norma EPCglobal. A partir dos resultados da simulação, é possível perceber que o mecanismo proposto apresenta desempenho 99% do DFSA ideal em redes densas, onde há grande quantidade de etiquetas. Em relação ao algoritmo Q, percebe-se a melhoria de 6,5% no desempenho. É importante ressaltar também a redução no consumo de energia do leitor em torno de 63% em relação ao DFSA ideal.

Redes de Computadores

DFSA (Dynamic Framed Slotted ALOHA)

Algoritmos Anticolisão

Computer Networks

Anti-collision algorithms

Power control

ENGENHARIAS: ENGENHARIA ELÉTRICA

Optimalizace ethernetové sítě ve výrobním podniku / Optimization of Ethernet network in manufacturing plant

Kratochvíl, Petr

January 2020

This diploma thesis describes the work performed in the optimization of the corporate network in the company Alps Electric Czech to expand the amount of information obtained about the state of the network and thus improve the response of the IT department to potencial errors. During the optimization, a monitoring system was also deployed and its connection to the helpdesk and a tailor-made website running on the Flask microframework. With the gradual deployment, adjustments were made based on feedback from the IT department staff. Overall, the network has become more clarified, increasing the efficiency of maintenance and service.

Simulátor provozu stanic s kmitočtovým skákáním a vyhýbáním se kolizí / Simulator of stations with frequency hopping and collision avoidance

Akkizová, Dinara

January 2011

The master's thesis aims to introduce and study the issue of frequency hopping with collsion avoidance (FH/CA). On this basis, design a computer program for simulating the operation of a radio systém FHCA, who works in the band used by other systems FH/CA . This simulation programm using MATLAB software to implement verify the correctness of programs. Use simulator to obtain date about the intensity of interference systems FH/CA for the chosen scenario. This work consists of five parts: the first part consists of describing the queuing system, the second part of the description of the radio frequency system with collision avoidence FH / CA, the third part of the description of the simulation model. The fourth part includes verification of the model in the fifth and last section inspects results are shown.

Výběr referenčních uzlů pro bezkotevní lokalizační techniky v bezdrátových senzorových sítích / Reference Nodes Selection for Anchor-Free Localization in Wireless Sensor Networks

Šimek, Milan

January 2010

Dizertační práce se zabývá návrhem nového bezkotevního lokalizačního algoritmu sloužícího pro výpočet pozice uzlů v bezdrátových senzorových sítích. Provedené studie ukázaly, že dosavadní bezkotevní lokalizační algoritmy, pracující v paralelním režimu, dosahují malých lokalizačních chyb. Jejich nevýhodou ovšem je, že při sestavení množiny referenčních uzlu spotřebovávají daleko větší množství energie než algoritmy pracující v inkrementálním režimu. Paralelní lokalizační algoritmy využívají pro určení pozice referenční uzly nacházející se na protilehlých hranách bezdrátové sítě. Nový lokalizační algoritmus označený jako BRL (Boundary Recognition aided Localization) je založen na myšlence decentralizovaně detekovat uzly ležící na hranici síti a pouze z této množiny vybrat potřebný počet referenčních uzlu. Pomocí navrženého přístupu lze znažně snížit množství energie spotřebované v průběhu procesu výběru referenčních uzlů v senzorovém poli. Dalším přínosem ke snížení energetických nároku a zároveň zachování nízké lokalizační chyby je využití procesu multilaterace se třemi, eventuálně čtyřmi referenčními body. V rámci práce byly provedeny simulace několika dílčích algoritmu a jejich funkčnost byla ověřena experimentálně v reálné senzorové síti. Navržený algoritmus BRL byl porovnán z hlediska lokalizační chyby a počtu zpracovaných paketů s několika známými lokalizačními algoritmy. Výsledky simulací dokázaly, že navržený algoritmus představuje efektivní řešení pro přesnou a zároveň nízkoenergetickou lokalizaci uzlů v bezdrátových senzorových sítích.

Utveckling av mätmetod och prestandaanalys av LoRa / Development of measurement method and performance analysis of LoRa

Gitijah, Parham

January 2019

Internet of Things(IoT) tillämpningar har ökat under de senaste åren och därför behövs nya kommunikationstekniker som uppfyller kriterierna låg strömförbrukning, lång räckvidd samt låg kostnad, som behövs för att distribuera tekniken i samhället. LoRa (Long Range) är en framstående trådlös kommunikationsteknik som utvecklades av LoRa Alliance för att uppfylla dessa kriterier.  Syftet med arbetet är att utveckla en mätmetod för prestandaanalys av radiosystemet LoRa. Mätmetoden används sedan för att analysera hur olika parametrar som datahastighet, avstånd och olika miljöer påverkar LoRa-nätverksprestandaparametrar dvs. signalstyrka, paketförluster, fördröjningar (latency) och fördröjningsvariationer (jitter).  För att uppnå syftet utvecklades först en mätningsmetod. Därefter genomfördes experiment i två olika miljöer (stadsmiljö och havsmiljö) för prestandaanalys av LoRa. I varje experiment positionerades en IoT-nod på olika avstånd och datapaket skickades med olika datahastigheter från IoT-noden till en gateway. Datahastigheten ändrades genom att ändra på spridningsfaktor (SF) och bandbredd. Passiv mätningsmetod användes för att samla in mätningsdata. Metoden som användes för att analysera resultaten var statistisk dataanalysmetod då de data som samlades in var kvantitativa.  Resultatet visar att signalstyrkan påverkas av miljö, avstånd och bandbredd. Signalstyrkan är starkare i fri sikt jämfört med stadsmiljö. Signalstyrkan är starkare även vid kortare avstånd och större bandbredd. Däremot har datahastigheten (SF) minimal påverkan på signalstyrkan. Att signalstyrkan påverkas av bandbredden är intressant resultat som inte kunde förutses innan. Paketförlusten påverkas av miljö, datahastighet (SF och bandbredd) och avstånd. Fler datapaket förloras vid längre avstånd och i stadsmiljön. Lägre datahastighet leder till att färre datapaket förloras och på så sätt längre kommunikationsräckvidd uppnås. Enligt tidigare arbetens simuleringar förutsågs att högre datahastighet leder till längre kommunikationsräckvidd men i den här studien genomfördes experiment på riktig hårdvara för att undersöka resultaten. Miljö, avstånd och datahastighet påverkar fördröjningen. Fördröjningen är några millisekunder längre i stadsmiljö än havsmiljö vid samma avstånd. Fördröjningen är även några millisekunder längre vid längre avstånd i samma miljö. Däremot har datahastighet största påverkan på fördröjningen. Fördröjningen ändras med några hundra millisekunder när datahastigheten ändras genom SF och/eller bandbredd.  Fördröjningsvariationen påverkas inte av miljö och avstånd. Datahastighet (bandbredd och SF) påverkar fördröjningsvariationen men denna påverkan är låg och man kan bortse från den. / The Internet of Things (IoT) use cases have increased significantly in recent years. Therefore, new wireless communication technologies are needed that meet the criteria such as low power consumption, long range and low cost. LoRa, which stands for "Long Range", is a wireless communication technology developed by the LoRa Alliance to meet these criteria.  The purpose of this paper is to a develop measurement method for performance analysis of the LoRa radio system. The measurement method used to analyze how different parameters such as data rate, distance and different environments affect LoRa network performance parameters i.e. signal strength, packet loss, latency and jitter. To achieve the purpose, a measurement method and prototype were first developed. Then experiments were carried out in two different environments (urban and open space). In each experiment, an IoT node was positioned at different distances and data packets were sent from the IoT node to a gateway with different data rates. The data rate was changed by changing the spreading factor (SF) and bandwidth. Passive measurement method was used to collect measurement data. The method used to analyze the results was the statistical data analysis method since the data collected was quantitative. The result shows that the signal strength is affected by the environment, distance and bandwidth. The signal strength is stronger in free view compared to urban environment. The signal strength is stronger even at shorter distances and greater bandwidth. However, the data rate (SF) has minimal impact on signal strength. The fact that the signal strength is affected by the bandwidth is interesting results that could not be predicted before. The packet loss is affected by the environment, data rate and distance. More data packets go lost at longer distances and in the urban environment. Lower data rate cause to fewer data packets go lost and a longer communication range being achieved. According to earlier work's simulations, it was possible to predict that higher data rates lead to longer communication range, but in this study experiments were carried out on real hardware to investigate the results. Environment, distance and data rate affect the delay. The delay is a few milliseconds longer in urban environment than the free space environment at the same distance. The delay is also a few milliseconds longer at longer distances in the same environment. However, data rate has the greatest impact on the delay. The delay changes by a few hundred milliseconds when the data rate is changed by SF and/or bandwidth. The jitter is not affected by the environment and distance. Data rate (bandwidth and SF) affects the delay variation but this influence is low and can be ignored.

LoRa

IoT

LPWAN

Internet of Things

signal strength

packet loss

latency

jitter

data rate

passive measurement

LoRa

LPWAN

IoT

datahastighet

bandbredd

signalstyrka

paketfördröjning

paketförlust

fördröjningsvariation

passiv mätning

Communication Systems

Kommunikationssystem

LoRa Radio Performance Analysis Based on AVR-RSS2 and RIOT-OS for Indoor IoT Applications

Yi, HongShuo, Dai, Duosi

January 2023

This thesis is dedicated to measuring the communication performance of LoRa technology in an indoor environment and providing insight into its potential application as an effective Internet of Things (IoT) communication solution in Low Power Wide Area Networks (LPWAN). Through careful experimentation and analysis, we assessed various transmission parameters such as spreading factor (SF), bandwidth (BW), Payload Length (PL), and LoRaWAN classes. Performance metrics including Receive Signal Strength Indicator (RSSI), Signal-to-Noise Ratio (SNR), Round-trip time (RTT), and Goodput are measured to evaluate LoRa’s performance under different settings. The research question addressed is whether LoRa can be effectively used for indoor wireless communication. Our findings demonstrate that LoRa technology exhibits good transmission range, reliability, and cost-effectiveness in indoor environments, making it suitable for some indoor IoT applications. We also examined the impact of different LoRaWAN device classes and highlighted the importance of balancing the SF and BW to optimize communication performance. In conclusion, this thesis offers a comprehensive understanding of the communication performance of LoRa technology in indoor environments, providing valuable guidance for its practical application in indoor IoT communication. The research findings presented herein serve as a significant reference for future research endeavors in this field, enabling further advancements in the domain of LoRa-based wireless communication technologies for indoor IoT applications. / Denna avhandling ägnas åt att mäta kommunikationsprestanda för LoRa-teknik i en inomhusmiljö och ger insikt i dess potentiella tillämpning som en effektiv kommunikationslösning för Internet of Things (IoT) i Low Power Wide Area Networks (LPWAN). Genom noggranna experiment och analys utvärderade vi olika överföringsparametrar som spridningsfaktor (SF), bandbredd (BW), nyttolastlängd och LoRaWAN-enhetens klasser. Prestandametriker inklusive Receive Signal Strength Indicator (RSSI), Signal-to-Noise Ratio (SNR), Round-trip time (RTT) och Goodput mäts för att utvärdera LoRa’s prestanda under olika inställningar. Forskningsfrågan som behandlas är om LoRa effektivt kan användas för inomhus trådlös kommunikation. Våra resultat visar att LoRa-teknik uppvisar bra överföringsområde, tillförlitlighet och kostnadseffektivitet i inomhusmiljöer, vilket gör det lämpligt för vissa inomhus-IoT-applikationer. Vi undersökte också inverkan av olika LoRaWAN-enhet klasser och framhävde vikten av att balansera SF och BW för att optimera kommunikationsprestanda. Sammanfattningsvis erbjuder denna avhandling en omfattande förståelse för kommunikationsprestanda för LoRa-teknik i inomhusmiljöer, vilket ger värdefull vägledning för dess praktiska tillämpning inom inomhus IoT-kommunikation. De forskningsresultat som presenteras här fungerar som en betydande referens för framtida forskningsinsatser inom detta område, vilket möjliggör ytterligare framsteg inom området för LoRa-baserade trådlösa kommunikationstekniker för inomhus IoT-applikationer.

LoRa

Indoor IoT (Internet of Things)

Signal strength

Round-trip time (RTT)

Goodput

LoRaWAN device classes

AVR-RSS2

RIOT-OS

LoRa

Inomhus-IoT (Internet of Things)

Signalstyrka

Rundresa-tid (RTT)

Goodput

LoRaWAN klasser

AVR-RSS2

RIOT-OS

Computer and Information Sciences

Data- och informationsvetenskap