Photonic Ultra-wide Band Monocycle Generation through Electro Absorption Modulator with Single Wavelength Light

Chen, Po-Yen

06 September 2010

Ultra Wide Band (UWB) is a short-pulse electrical signal which is widely used for short distant wireless communication because its low path loss, good immunity to multipath propagation, and high data rate. The reason of using optical fiber as carrier is fiber can bust up the communication capacitance in long distance range because of high capacitance, low loss propagation. Thereby, the technique of UWB signal on fiber has become more and more important. In this work, a novel method using electro-absorption modulation with short termination for interface of optical fiber and generate UWB signal is proposed and demonstrated. The structure is simple.This method don¡¦t need employing any complicated frequency mixer, or complex systems. This work need to generate optical pulse with high energy, which is feded into the EAM. The signal can generate electrical pulse and build electrical field on EAM in the same time. The optical pulse is modulated by the electrical field on EAM. Using this way, we can generate UWB optical signal.

ultra-wide band

EAM

seed

monocycle pulse

The Study and Fabrication of Ultra-Wideband Optical Amplifier Based on Cr4+:YAG Crystal Fiber

Chen, Shao-syuan

04 July 2007

The maximum capacity of an optical fiber transmission system more than doubled every year to match the fast-growing communication need. The technology break through in dry fiber fabrication opens the possibility for fiber bandwidth all the way from 1300nm to 1600nm. The fast increasing demand of communication capacity results in the emergence of wavelength division multiplexing (WDM) technology, which results in the need for ultra-wideband optical amplifier. Cr4+:YAG has a strong spontaneous emission that covers 1300nm to 1600nm. Besides, its absorption spectrum is between 900nm to 1200nm, which matches with the pumping source in current erbium doped optical amplifier. Such a fiber is, therefore, eminently suitable for optical amplifier applications. In this article, we will introduce the development of ultra-wideband optical amplifier using the double-clad Cr4+:YAG crystal fiber, which is grown by laser heated pedestal growth(LHPG) technique. Its material properties as well as optical gain will be characterized. By butt-coupling method, a low insertion loss of 4.2 dB was achieved in a SMF-CDF-SMF configuration, and it was measured to demonstrate a gross gain of 2.4 dB at 1 W bi-directional pump power. Moreover, theoretical models and numerical simulations have been developed to predict the experimental results. Numerical simulation indicates that the efficiency of mode overlapping between signal and pump is crucial to gain performance. The mode overlapping efficiency is about 25%~30% for our crystal fiber under current circumstances. In the future, we will make an attempt to reduce the index contrast between core and cladding for better mode overlapping efficiency. At the same time, we also try to grow crystal fiber of smaller core diameter to improve gain performance.

ultra-wide band

crystal fiber

fiber amplifier

Optical Ultra-Wide-Band Pulse generation by Quantum Well-Waveguide device

Chou, Yi-fen

06 August 2008

Ultra Wide Band (UWB) is a short-pulse electrical signal, which is widely used for short distant wireless communication due to its low path loss, good immunity to multipath propagation, and high data rate. The main target transmission area of UWB is within 10 meters. Using optical fiber as carrier can bust up the communication capacitance in long distance range because of high capacitance, low loss propagation, and TDM and WDM compatible properties of fiber. Thereby, the technique of UWB on fiber has become more and more important. In this work, a novel method using waveguide photodetector (WP) with short termination for interface of optical fiber and wireless is proposed and demonstrated. The structure is simple without employing any complicated frequency mixer, intermediate frequency, or complex systems. This work is divided into two parts: (1) generation of UWB electrical signals and (2) wavelength conversion of UWB through WP. In the former, a WP with short termination is used in the device. The photocurrent excited by short optical pulse is distributive generated through the waveguide, forming two opposite directions of electrical waves. By reflection on the short termination, the reversed phase of one electrical wave is added to another electrical wave through a delay line, forming a monocycle of UWB signal. By appropriate design on the length of waveguide, the band of 2-10GH is demonstrated, fitting the requirement of FCC (Federal Communications Commission). In the second part of this paper is the wavelength conversion of UWB. The active region of WG is multiple quantum wells (M.Q.W.), which is not only served as photo-absorption layer, but also can be used the electroabsorption material. By pumping M.Q.W.s with high optical power, the cross absorption properties can be applied for wavelength conversion. By pumping power of 12dBm, the wavelength-converted UWB signal is successfully demonstrated at range of 1545nm-1570nm. Using this method, the application of UWB on router of fiber optical network is expectable.

Ultra Wide Band

waveguide photodetector

wavelength conversion

Ultra-Wideband Microwave Ablation Applicators

Asili, Mustafa

17 May 2014

The increasing demand for efficient cancer treatment inspired the researchers for new investigations about an alternative treatment of cancer. Microwave ablation is the newest ablation technique to cure cancer. This method is minimally noninvasive and inexpensive compared to the other methods. However, current microwave ablation systems suffer due to narrowband nature of the antenna (dipole or slot) placed at the tip of the probe. Therefore, this study developed an ultra-wideband ablation probe that operates from 300MHz to 10 GHz. For this purpose, a small wideband antenna is designed to place at the tip of the probe and fabricated. These probes are tested at ISM frequencies (2.4 GHz and 5.8GHz) in skin mimicking gels and pig liver. Microwave ablation probe design, simulation results, and experiment results are provided in this thesis.

ultra wide band applicators

microwave ablation

Generalized Maximum-Likelihood Algorithm for Time Delay Estimation in UWB Radio

Tsai, Wen-Chieh

24 July 2004

The main purpose of this thesis is to estimate the direct path in dense multipath Ultra Wide-Band (UWB) environment. The time-of-arrival (ToA) estimation algorithm used is based on Generalized Maximum-Likelihood (GML) algorithm. Nevertheless, GML algorithm is so time-consuming that the results usually take a very long period of time, and sometimes fail to converge. Hence, the schemes that would improve the algorithm are investigated. In the schemes, the search was executed in sequential form. Two threshold parameters are to be determined¡Xone is about the arrival time of the estimation path while the other is the fading amplitude of the estimation path. The thresholds are determined in order to terminate the sequential algorithm. The determination of thresholds is based on error analysis, including the probability of error and root-mean-square error. The analysis of the probability of error is subject to the probability of false alarm and the probability of miss. However, a trade-off problem on the probability of false alarm and the probability of miss exists in the process of determining thresholds. The thresholds are determined according to the requirement of the probability of error. We propose an improvement scheme for determining the two thresholds. In the proposed scheme, candidate pairs are evaluated within an appropriate range. The root-mean-square error value for each pair of thresholds is calculated. The smallest error, corresponding to the desired thresholds, is chosen for use in ToA estimation. From the simulation results, it is seen that, when SNR falls between -4dB and 16dB, the improvement proposed scheme results has the smaller estimation error.

Ultra Wide-Band

Time Delay

Generalize Maximum Likelihood

On The Design Of Wideband Antennas Using Mixed Order Tangential Vector Finite Elements

Karacolak, Tutku

05 August 2006

A 3D Finite Element Boundary Integral technique (FE-BI) using mixed-order tangential vector finite elements (TVFE?s) is presented. This technique is used to design two wide band antennas and an ultra wideband (UWB) antenna array. Tetrahedral elements are used for domain discretization because they offer higher flexibility when simulating complex structures. A set of hierarchical mixed-order TVFE?s up to and including order 2.5 is implemented. Hierarchical mixed-order TVFE?s accurately simulate regions with high and low field variations. They also guarantee tangential field continuity across element boundaries and suppress spurious modes. The efficacy of the technique has been tested on two different wide band antennas and an UWB array. The first antenna is designed for automotive applications and covers GPS, GSM, XM, and PCS bands (0.8?3.35 GHz). The second antenna is a double sided rounded bowtie antenna (DSRBA) for UWB communication (3.1-10.6 GHz). The third design is a DSRBA array. For validation purposes, the antennas are also simulated using a commercially available high frequency electromagnetic simulation software, HFSS. Results regarding antenna parameters such as return loss, radiation pattern, and gain are also given.

ultra wide band

rounded patch

phased array

Dolph-Tschebyscheff

Μελέτη και υλοποίηση τεχνικής ισοστάθμισης για UWB σύστημα με διαμόρφωση PPM

Τζένος, Δημήτριος

27 February 2009

Οι τεχνικές ασύρματης μετάδοσης Ultra Wide Band (UWB) είναι γνωστές εδώ και αρκετές δεκαετίες. Το ϐασικό χαρακτηριστικό των συγκεκριμένων συστη- μάτων είναι η εκπομπή και λήψη σήματος που εκτείνεται σε πολύ μεγάλο εύρος συχνοτήτων. Τα τελευταία χρόνια παρατηρείται διαρκώς αυξανόμενο ερευνητικό ενδιαφέρον γύρω από την περιοχή των τηλεπικοινωνιακών συ- στημάτων που χρησιμοποιούν UWB τεχνικές μετάδοσης, κυρίως λόγω της μεγάλης εφαρμοσιμότητάς της. Στις τηλεπικοινωνιακές εφαρμογές, η χρήση της τεχνικής UWB μπορεί να οδηγήσει σε αύξηση των ταχυτήτων ασύρματης μετάδοσης, λόγω της δυνατότητας εκπομπής μεγάλου αριθμού παλμών σε πολύ μικρό χρονικό διάστημα. Σε εφαρμογές εντοπισμού, το UWB μπορεί να ωθήσει προς την αύξηση της διακριτικής τους ικανότητας. Επίσης, κατάλ- ληλα UWB σήματα μπορούν να χρησιμοποιηθούν όπου υπάρχει ανάγκη για υψηλή διεισδυτικότητα μέσα από εμπόδια. Ο πιο απλός τρόπος μετάδοσης σήματος τέτοιου είδους είναι η εκπομ- πή εξαιρετικά σύντομων παλμών. Ο τρόπος με τον οποίο τα μεταδιδόμενα σύμβολα διαμορφώνουν αυτούς τους παλμούς ποικίλλει. Οι πρώτες UWB εφαρμογές χρησιμοποιούσαν σχεδόν αποκλειστικά την τεχνική Dιαμόρφωσης Θέσης Παλμού (Pulse Position Modulation PPM) γιατί η αντιστροφή πολύ σύντομων παλμών ήταν δύσκολο να υλοποιηθεί. Με αυτή την τεχνική, το κάθε μεταδιδόμενο σύμβολο καθορίζει τη ϑέση του παλμού στο πεδίο του χρόνου. Αργότερα, άρχισαν να χρησιμοποιούνται και τεχνικές Dιαμόρφωσης Πλάτους Παλμού (Pulse Amplitude Modulation PAM). Wστόσο, ένα μεγάλο πλεονέκτημα της μεθόδου PPM είναι οι μειωμένες απαιτήσεις της σε ισχύ, γιατί μεταδίδονται πολύ σύντομοι παλμοί ακολουθούμενοι από σχετικά με- γάλες περιόδους «σιωπής». Η ιδιότητα αυτή, καθιστά τη μέθοδο διαμόρφωσης PPM ιδιαίτερα ελκυστική σε εφαρμογές που απαιτούν χαμηλή κατανάλωση ισχύος. Σε αυτή την εργασία μελετούμε τη δομή ενός συστήματος μετάδοσης δε- δομένων Ultra Wide Band το οποίο χρησιμοποιεί τη μέθοδο διαμόρφωσης PPM. Η συμπεριφορά ενός τέτοιου συστήματος κατά τη μετάδοση μέσα από διάφορα κανάλια παρουσία ϑορύβου εξετάζεται μέσω εξομοίωσης. Είναι γνω- στό ότι τα συστήματα αυτά πλήττονται τόσο από το ϑόρυβο που εισάγεται λό- γω της μετάδοσης, διασυμβολική παρεμβολή, αλλά και παρεμβολή ανάμεσα στους πολλαπλούς χρήστες. Επίσης, οι περιορισμοί που ορίστηκαν στις ΗΠΑ για την μεταδιδόμενη ισχύ ανά συχνότητα των εμπορικών UWB εφαρμογών, οι οποίοι αναμένεται να υιοθετηθούν και στον υπόλοιπο κόσμο, αποτελούν ένα επιπλέον ϑέμα που επηρεάζει την επίτευξη υψηλών ϱυθμών μετάδοσης δεδομένων. Μια λύση είναι η χρήση τεχνικών ισοστάθμισης ή, ισοδύναμα, μεθόδων εκτίμησης του καναλιού που λειτουργούν στο δέκτη. Αν και οι κλασικές τεχνικές ισοστάθμισης ή εκτίμησης καναλιού μπορούν να εφαρμο- στούν με μικρές τροποποιήσεις και σε UWB σήματα διαμορφωμένα με PPM, ένα ϐασικό εμπόδιο είναι τόσο το μεγάλο πλήθος παραμέτρων που πρέπει να εκτιμηθούν (ένα τυπικό κανάλι σε εσωτερικό χώρο μπορεί να έχει ακόμη και πάνω από 150 συντελεστές), όσο και ο πολύ μεγάλος ϱυθμός δειγματοληψίας που απαιτείται. Επίσης, ϕαίνεται ότι μπορούν να αξιοποιηθούν τα ιδιαίτερα χαρακτηριστικά που εμφανίζει η εφαρμογή της διαμόρφωσης PPM σε UWB συστήματα, όπως είναι το ϕαινόμενο πολλαπλών μονοπατιών (multipath) σε συνδυασμό με την υψηλή διακριτικότητα (resolution) του σήματος UWB, ή ακόμη και η δυνατότητα μετάδοσης του ίδιου συμβόλου περισσότερες από μί- α ϕορές. Στα πλαίσια της εργασίας ϑα μελετηθούν και ϑα ενσωματωθούν στο σύστημα υπάρχουσες μέθοδοι εκτίμησης ή ισοστάθμισης καναλιού, οι οποί- ες αποτελούν προϊόν πρόσφατων προσπαθειών προς αυτή την κατεύθυνση. Θα μελετηθεί ο τρόπος με τον οποίο επιδρούν στην απόδοση του συστήμα- τος. Τέλος, ϑα εξεταστεί η δυνατότητα επέκτασης των μεθόδων εκτίμησης καναλιού με σκοπό τη ϐελτίωση της υπολογιστικής τους πολυπλοκότητας, μετατρέποντάς τους σε επαναληπτικούς/προσαρμοστικούς αλγορίθμους. / -

Ραδιοσήματα

Κανάλια

621.382 1

Ultra Wide Band (UWB)

Pulse Position Modulation (PPM)

Investigation of ultra-wideband wireless communication inside electromagnetically ultra small confined environments

Gelabert, Javier

January 2012

Ultra-wideband (UWB) communication has been the subject of extensive research in recent years due to its unique capabilities and potential applications, particularly in short-range multiple access wireless communications. However, many important aspects of UWB-based communication systems have not yet been thoroughly investigated. The propagation of UWB signals inside very small enclosed environments is one of the important issues with significant impacts on the future direction, scope, and generally the extent of the success of UWB technology. The objective of this thesis is to obtain a more thorough and comprehensive understanding of ultra-small UWB channels for communication applications and design issues for enhancing the data rate of UWB systems. This works supports the postulation of a high capacity UWB wireless interconnect scheme for communicating devices within conducting enclosures – a wireless “backplane”. This thesis proposes the use of an Ultra-Wide Bandwidth (UWB) ultra-small scale wireless interconnect scheme for use within electrically small enclosures. Such ultra-small environments (size ≤ 10 wavelengths) are topologically much more complex, being more cluttered, than typical indoor environments (size ≥ 10 wavelengths). The concept is presented through two different scenarios. Firstly, a PC Tower case is presented as a model environment and the work seeks to present the optimum channel performance, where EMI issues are discussed and problem avoidance proposed. Secondly, in order to extrapolate the different results from the study inside the PC, an investigation is carried out using an Aluminium tower case as a more generic model environment. The analysis is based on the behaviour of box modes within a conducting resonator enclosure and the effective communications bandwidth for UWB systems for different sizes and components within. From these general considerations the research presents theoretical and experimental results from which are derived the communications metrics measured within enclosures. Simulations of the different scenarios are performed using different techniques such as ray tracing and a full wave model, based on CST Microstripes. Empirical data is recorded using a vector network analyser (VNA)-based wideband channel sounding system where channel measurements are carried out in every scenario regarding different aspects such as frequency response and time domain analysis, evaluation of the channel capacity, power delay study and the nature of the environment.

621.384

Ultra Wide Band Sigma-Delta modulator in CMOS090 / UWB Sigma-Delta modulator i CMOS090

Jonsson, Fredrik

January 2004

<p>Today the frequency spectrum is full of wireless standards. The most common technique being used is the frequency modulation. To take advantage of this and the technology improvement a new wireless communication standard is being developed. This standard is using a low power impulse modulation method, allowing it to overlap with other standards. The proposed standard called IEEE802.15.3a is applied at an Ultra Wide Band and has potential to be used both in interchip and intrasystem communication, since it allows a very high data density. </p><p>In this thesis the analog to digital converter is designed, which is one part of a communication system. Although the signal bandwidth is very wide the converter is designed as a Sigma-Delta modulator, which is most suitable for low-speed applications. Its main advantages over high-speed converters are less area and less power consumption. The goal of this project is to investigate if the CMOS090 process technology will be sufficient for reaching a signal-to-noise ratio, SNR, of 30 dB in a signal band of 264 MHz. </p><p>The main limiting factor during the design of the modulator is the excess feedback delay. This delay degrades the SNR and can even make the system unstable. At a feedback delay of 83 ps and a sampling frequency of 6.336 GHz, the maximum SNR achieved was 27 dB. At this high frequency the modulator is close to instability. Hence, to ensure stability a maximum sampling frequency of 4.224 GHz is chosen, achieving a SNR of 19 dB. </p><p>The effect of the feedback delay can be reduced either by using a different structure or by using compensation methods, either of them would probably allow a SNR above 30 dB.</p>

Electronics

Sigma-Delta modulator

Ultra Wide Band

UWB

Excess feedback delay

CMOS090

Elektronik

Electronics

Elektronik

UWB Antennas for Wall Penetrating Radar Systems

Javashvili, Otar

January 2009

<p>Basic properties and new design principles of ultra wideband Vivaldi antennas are presentedand discussed in this paper. The focus will be on the modeling of Vivaldi antenna design curves, by which it is constructed; its simulation results, realization and the measurements.</p><p>According to the aim of this research the discussion starts with the review of the previous researches done for Vivaldi antennas. Introductory part of the report also contains the problem description for the current project and the classification of the goals to be achieved. As a theoretical review, the discussion initiates with the definitions anddescription of basic parameters of the antennas and covers a short presentation of UWBpulse-based radar system. The attention will be focused on UWB signals behavior and characterization, their propagation principles and basic troubles stands nowadays. As anapplication the wall penetrating Radar systems will be considered. The major part of thereport holds on the investigation of the design principles of Vivaldi Antenna andoptimization of the key parameters for achieving the best performance for radar. Theending part of the report shows the simulations and measurement results and theircomparisons following with conclusions/discussions.</p><p>The report will be supportive for the antenna designers, who work for UWB systems andparticularly for Vivaldi antennas, as long as there are showing up detailed descriptions ofVivaldi antenna characteristics depending on its shape and substrate properties. The modelfor designing Vivaldi antennas, given in this project, can successfully be applied for almostall the cases used in practice nowadays.</p>

Vivaldi Antenna

Ultra-wide Band

Radar

Wireless Communications

Electrical engineering

Elektroteknik