Broadband wireless communications: issues of OFDM and multi-code CDMA

Sathananthan, K.

January 2003

Abstract not available

Wireless communication systems

Broadband communication systems

Code division multiple access

Orthogonalization methods

Wavelength division multiplexing

Long-Wavelength Vertical-Cavity Lasers : Materials and Device Analysis

Mogg, Sebastian

January 2003

Vertical-cavity lasers (VCLs) are of great interest as lightsources for fiber-optic communication systems. Such deviceshave a number of advantages over traditional in-plane laserdiodes, including low power consumption, efficient fibercoupling, on-chip testability, as well as potential low-costfabrication and packaging. To date, GaAs-based VCLs operatingat 850 nm are the technology of choice for short-distance,high-speed data transmission over multimode fiber. Forlong-distance communication networks, long-wavelength (LW) VCLsoperating in the 1.3 and 1.55-&#956m transmission windowsof standard singlemode fibers are desired. However, despiteconsiderable worldwide development efforts, the commercialbreakthrough of such devices has still to be achieved. This ismainly due to shortcomings of the intrinsic material propertiesof InP-based material systems, traditionally employed in LWlaser diodes. While LW quantum well (QW) active regions basedon InP are well established, efficient distributed Braggreflectors (DBRs) are better built up in the AlGaAs/GaAsmaterial system. Therefore, earlier work on LW VCLs has focusedon hybrid techniques such as bonding between InP-based QWs andAlGaAs/GaAs DBRs using waferfusion. More recently, however, themain interest in this field has shifted towards all-epitaxialGaAs-based devices employing novel 1.3-&#956m activematerials with strained GaInNAs QWs as one of the mostpromising candidates. The main focus of this thesis is on the characterization andanalysis of LW VCLs and building blocks thereof, based on bothInP and GaAs substrates. This includes a theoretical study on1.3-&#956m InGaAsP/InP multiple QW active regions, as wellas an experimental investigation of novel, highly strained1.2-&#956m InGaAs/GaAs single QWs. Two high-accuracyabsolute reflectance measurement setups were built for thecharacterization of various DBRs. Reflectance measurementsrevealed that n-type doping is much more detrimental to theperformance of AlGaAs/GaAs DBRs than previously anticipated.Near-room temperature operation of a single-fused1.55-&#956m VCL with an InP/InGaAsP bottom DBR wasobtained. A thermal analysis of this device structure clearlyindicated its limited capabilities in terms of high-temperatureoperation. As a result, further efforts were directed towardsall-epitaxial GaAs-based VCLs. Record-long emission wavelengthsto above 1260 nm were obtained from InGaAs VCLs based on anextensive gain–cavity detuning. These devices showed verypromising performance characteristics in terms of thresholdcurrent and light output power, indicating good potential forbeing a viable alternative to GaInNAs-based VCLs.

VCL

VCSEL

vertical-cavity laser

semiconductor laser

long-wavelength

DBR

characterization

analysis

InP

InGaAs

quantum well

numerical modeling

Electromagnetic simulation and design of etched diffraction grating demultiplexers

Song, Jun

January 2008

Among various planar lightwave circuits for multiplexing/demultiplexing in an optical communication system, etched diffraction gratings (EDGs) have shown great potential due to their compactness and high spectral finesse. Conventional numerical methods for grating simulation cannot be used to simulate an EDG demultiplexer of large size (in terms of the wavelength). In the present thesis, the polarization-dependent characteristics of an EDG demultiplexer are analyzed with a boundary element method (BEM) for both an echelle grating coated with a metal and a dielectric grating with total internal reflection (TIR) facets. For EDGs with metal-coated facets, we use a more effective method, namely, method of moments (MoM). Futhermore, a fast simulation method for EDGs with TIR facets is presented based on the Kirchhoff–Huygens principle and the Goos-Hänchen shift. This simple method has a good agreement with a BEM over a wide range of practical parameters of the device. Several novel designs are presented in order to improve the performances of EDGs. (1) By making some appropriate roughness on the surface of the shaded facets, the PDL of the demultiplexer can be effectively reduced over a large bandwith. (2) For EDGs based on Si nanowire structures, we compensate the polarization-dependent wavelength dispersion (PDλ) in the whole operational spectrum by introducing a polarization compensation area in its free propagation region. (3) An EDG demultiplexer with suppressed sidelobe is designed. The designed EDG demultiplexer can give a crosstalk as small as 50 dB in theory. (4) By chirping the diffraction order for each facet, we minimize the envelope intensity for the other adjacent diffraction orders to achieve a negligible return loss in a large spectral width. (5) A design for EDG demultiplexers is presented to obtain both large grating facets and a larger free spectral range (FSR) using the optimal chirped diffraction orders for different facets. The influences of the fabrication errors (e.g., rounded effect, surface roughness and point defect in the waveguide) on the performance (such as the insertion loss, the polarization dependent loss and the chromatic dispersion) of an EDG demultiplexer are also analyzed in detail. Silicon nanowire waveguides and related EDGs are studied. An EDG demultiplexer with 10 nm spacing is finally fabricated and characterized. / QC 20100910

etched diffraction grating

wavelength division multiplexing

passive devices

diffraction grating

planar waveguide devices

DWDM

optical communication.

Photonics

Fotonik

Integrated Optoelectronic Devices and System Limitations for WDM Passive Optical Networks

Taebi Harandi, Sareh

January 2012

This thesis puts focus on the technological challenges for Wavelength Division Multiplexed Passive Optical Network (WDM-PON) implementation, and presents novel semiconductor optical devices for deployment at the optical network unit (ONU). The first-ever reported L-band Reflective semiconductor optical amplifier (RSOA) is presented based on InP-base material. A theoretical model is developed to estimate the optical gain and the saturation power of this device compared to a conventional SOA. Experiments on this device design show long-range telecom wavelength operation, with polarization-independent gain of greater than 20 dB, and low saturation output power of 0 dBm suitable for PON applications. Next, the effect of the amplified spontaneous emission noise of RSOA devices on WDM-PON system is investigated. It is shown through theoretical modeling and simulations that the RSOA noise combined with receiver noise statistics increase probability of error, and induce considerable power penalties to the WDM-PON system. By improving the coupling efficiencies, and by distributing more current flow to the input of these devices, steps can be taken to improve device noise characteristics. Further, in spectrally-spliced WDM-PONs deploying RSOAs, the effect of AWG filter shape on system performance is investigated. Simulation modeling and experiments show that deployment of Flat-band AWGs is critical for reducing the probability of error caused by AWG spectral shape filtering. Flat-band athermal AWGs in comparison to Gaussin-shape counterparts satisfy the maximum acceptable error probability requirements, and reduce the power penalty associated with filtering effect. In addition, detuning between two AWG center wavelengths impose further power penalties to the WDM-PON system. In the last section of this thesis, motivated by RSOA device system limitations, a novel injection-locked Fabry-Perot (IL-FP) device is presented which consists of a gain section monolithically integrated with a phase section. The gain section provides locking of one FP mode to a seed source wavelength, while the phase modulator allows for adjusting the wavelength of the internal modes by tuning bias current to maintain mode-locking. This device counters any mode drifts caused by temperature variations, and allows for cooler-less operation over a wide range of currents. The devices and the performance metrics subsequently allow for a hybrid integration platform on a silicon substrate and integrate many functionalities like reflective modulator with thin film dielectric filter and receiver on a single chip for deployment at the user-end of future-proof low cost WDM-PONs.

Wavelength Division Multiplexing

Passive Optical Networks

Optoelectronic Devices

Injection-Locked Laser Sources

Electrical and Computer Engineering

Growth and Applications of Periodically Poled Lithium Niobate Crystal Fibers

Lee, Li-Min

07 September 2010

¡@¡@We integrated the laser-heated pedestal growth (LHPG) system with accurately controlled electrodes to build up our in situ poling system. The ZnO and MgO doped periodically poled lithium niobate crystal fiber were fabricated with the poling system. This poling system has the advantage of convenience and fast growth, but the ¡§screen effect¡¨ caused by free charges which exist near the molten zone must be eliminated. The micro swing resulted from the electric force is a feasible solution, because it can disarrange the free charges and reduce the ¡§screen effect¡¨. However, without excellently controlled micro swing, the uniformity of the poled domain pitch will loose and the conversion efficiency can not be improved. After analysis of the measured current data, the approximate system current model was presented and the proportional dependence between system current and micro swing was verified. Thus the system current was applied as the micro swing feedback signal, with that the variation of the micro swing was reduced from 25% to 15%. The stability of CO2 laser power is also a dominant factor to determine the quality of poled crystal fiber. The variation of the CO2 laser power was controlled within 1%. All the complicated works and precise control during the crystal fiber growth were accomplished with the LabVIEW program. ¡@¡@A novel and simple self-cascaded SHG + SFG scheme is presented for the generation of tunable blue/green light using ZnO doped periodically poled lithium niobate crystal fiber (PPLNCF) with a single designed pitch. A PPLNCF with a uniform period of 15.45£gm, the maximum conversion efficiency for the second harmonic generation and the cascaded SHG + SFG blue light can reach up to -9.2 dB and -31.9 dB, respectively. The 3 dB bandwidth of the tunable blue light is 3 nm (475-478 nm). In order to expand the tuning bandwidth range, a QPM gradient periodical structure was designed and can provide a 3 dB bandwidth of 65 nm for the tunable blue/green light output by simulation. We have successfully grown a crystal fiber with the domain pitch of 18.9 £gm for the C-band wavelength converter. The crystal length is 1.8 mm, the effective nonlinear coefficient of the lithium niobate crystal fiber is 18.2 pm/V that equals 0.53¡Ñdideal (34.4 pm/V). The conversion efficiency for converting the CW laser in C-band is about -59.3 dB.

wavelength converter

crystal fiber

second harmonic generation

laser-heated pedestal growth (LHPG)

A Wavalength Selectable Wdm Source Using A Fiber Sagnac Loop Filter

Ergul, Ozgur

01 September 2006

The demand for faster data transmission has been increasing since the wide acceptance of the Internet. To meet this ever increasing demand, optical communication systems use Wavelength Division Multiplexing (WDM) to transport more information per fiber by utilizing multiple wavelength channels. Multi-wavelength laser sources are one of the most important components of such WDM systems. In this thesis a multi-wavelength laser source is proposed. A fiber Sagnac loop filter is used to produce a grid pattern with peaks at a certain set of wavelengths. Then any desired channel is chosen from the grid by using an adjustable Fiber Bragg Grating.

Long-Wavelength Vertical-Cavity Lasers : Materials and Device Analysis

Mogg, Sebastian

January 2003

<p>Vertical-cavity lasers (VCLs) are of great interest as lightsources for fiber-optic communication systems. Such deviceshave a number of advantages over traditional in-plane laserdiodes, including low power consumption, efficient fibercoupling, on-chip testability, as well as potential low-costfabrication and packaging. To date, GaAs-based VCLs operatingat 850 nm are the technology of choice for short-distance,high-speed data transmission over multimode fiber. Forlong-distance communication networks, long-wavelength (LW) VCLsoperating in the 1.3 and 1.55-&#956m transmission windowsof standard singlemode fibers are desired. However, despiteconsiderable worldwide development efforts, the commercialbreakthrough of such devices has still to be achieved. This ismainly due to shortcomings of the intrinsic material propertiesof InP-based material systems, traditionally employed in LWlaser diodes. While LW quantum well (QW) active regions basedon InP are well established, efficient distributed Braggreflectors (DBRs) are better built up in the AlGaAs/GaAsmaterial system. Therefore, earlier work on LW VCLs has focusedon hybrid techniques such as bonding between InP-based QWs andAlGaAs/GaAs DBRs using waferfusion. More recently, however, themain interest in this field has shifted towards all-epitaxialGaAs-based devices employing novel 1.3-&#956m activematerials with strained GaInNAs QWs as one of the mostpromising candidates.</p><p>The main focus of this thesis is on the characterization andanalysis of LW VCLs and building blocks thereof, based on bothInP and GaAs substrates. This includes a theoretical study on1.3-&#956m InGaAsP/InP multiple QW active regions, as wellas an experimental investigation of novel, highly strained1.2-&#956m InGaAs/GaAs single QWs. Two high-accuracyabsolute reflectance measurement setups were built for thecharacterization of various DBRs. Reflectance measurementsrevealed that n-type doping is much more detrimental to theperformance of AlGaAs/GaAs DBRs than previously anticipated.Near-room temperature operation of a single-fused1.55-&#956m VCL with an InP/InGaAsP bottom DBR wasobtained. A thermal analysis of this device structure clearlyindicated its limited capabilities in terms of high-temperatureoperation. As a result, further efforts were directed towardsall-epitaxial GaAs-based VCLs. Record-long emission wavelengthsto above 1260 nm were obtained from InGaAs VCLs based on anextensive gain–cavity detuning. These devices showed verypromising performance characteristics in terms of thresholdcurrent and light output power, indicating good potential forbeing a viable alternative to GaInNAs-based VCLs.</p>

VCL

VCSEL

vertical-cavity laser

semiconductor laser

long-wavelength

DBR

characterization

analysis

InP

InGaAs

quantum well

numerical modeling

New methods for evaluation of tissue creping and the importance of coating, paper and adhesion

Boudreau, Jonna

January 2013

The creping process and the conditions on the Yankee cylinder dryer are key factors in a tissue paper mill, and they therefore need to be kept under good control in order to maintain a high and uniform quality. To this end it would be valuable to be able to make on-line measurements of Yankee coating thickness as well as the crepe structure of the tissue paper. The adhesion of paper to the cylinder affects the creping process and more information about the parameters that affect the adhesion is therefore of interest. To perform trials on a full scale or in a pilot plant is very costly and laboratory creping equipment is therefore sought after in order to be able to measure the adhesion force. The coating layer for use on the cylinder was analysed. It contained a large amount of carbohydrates and could not be considered transparent. The thickness of the coating layer was measured on a laboratory cylinder with a method based on fluorescence. An optical brightener was added to the coating chemicals and the coating layer was subjected to UV-radiation. The intensity of the light emitted by the optical brightener was measured and gave an indication of the thickness of the coating layer. The equipment has to be further investigated before it is possible to implement the new sensor on-line. New creping equipment and an adhesion method were developed for use on a laboratory scale. The equipment can operate with different creping angles and the force needed to crepe the paper can be measured. The highest creping force was obtained for papers of high grammage, low dryness at adhesion, high drainability, high fines content and high hemicellulose content. A more direct method is to analyse the structure of the produced paper. Measurements were made on a tissue paper with an optical fibre sensor while the paper was travelling at low speed. The collected signal was mathematically analysed and the characteristic wavelength was calculated for different paper samples. These values were close to the wavelengths measured with an off line method by a commercial crepe analyser. / Baksidestext The creping process is the heart of tissue paper manufacture. To control the process better, on-line measurements of paper structure and coating thickness are sought after. The creping is highly dependent on the adhesion of the paper to the Yankee dryer. To be able to measure the adhesion, laboratory creping equipment was also required. Different pulp parameters affect the adhesion and some of them have been investigated in this work. The coating on the Yankee cylinder consisted mainly of fiber fragments and could not be considered as transparent, which had to be considered when choosing a method to measure coating thickness. A method based on the light emitted from an optical brightener in the coating when subjected to UV-irradiation was used, but has to be further improved before it can be used on-line. A new laboratory creping method was developed to determine the adhesion between paper and metal, and the force needed to scrape off the paper with a doctor blade was measured. The highest creping force was obtained for papers made of pulp with a high drainability, high fines content and high hemicellulose content. An optical method using reflected light to measure crepe wavelength on-line was developed. The paper travelled under a sensor and the light collected was mathematically analyzed to determine the most common wavelength.

tissue

creping

paper adhesion

Tissue paper

creping

paper adhesion

coating layer

adhesives

Yankee cylinder

crepe structure

wavelength measurements

Multivariable And Sensor Feedback Based Real-Time Monitoring And Control Of Microalgae Production System

Jia, Fei

January 2015

A multi-wavelength laser diode based optical sensor was designed, developed and evaluated for monitoring and control microalgae growth in real-time. The sensor measures optical density of microalgae suspension at three wavelengths: 650 nm, 685 nm and 780 nm, which are commonly used for estimating microalgae biomass concentration and chlorophyll content. The sensor showed capability of measuring cell concentration up to 1.05 g L⁻¹ without sample dilution or preparation. The performance of the sensor was evaluated using both indoor photobioreactors and outdoor paddle wheel reactors. It was shown that the sensor was capable of monitoring the dynamics of the microalgae culture in real-time with high accuracy and durability. Specific growth rate (μ) and ratios of optical densities (OD ratios) at different wavelengths were calculated and were used as good indicators of the health of microalgae culture. A series of experiments was conducted to evaluate the sensor's capability of detecting environmental disturbances in microalgae systems, for instance, induced by dust or Vampirovibrio chlorellavorus, a bacteria found to cause crash of microalgae culture. Optical densities measured from the sensor were insensitive to the amount of dust that consisted of 59.7% of dry weight of microalgae in the system. However, the sensor was able to detect multiple events of introduction of dust timely by μ and OD ratios. The sensor was also capable of detecting subtle changes of culture in color that leads to a total crash of the culture before it can be differentiated by naked eye. The sensor was further integrated into an existing outdoor raceway to demonstrate the sensor's potential of being a core component to control microalgae production system. A real-time monitoring and control program along with a graphical user interface (GUI) was developed for a central control station aiming at improving resource use efficiency for biomass production.

Microalgae

Multi-wavelength

Optical density

Real-time monitoring and control

Vampirovibrio chlorellavorus

Early detection

Δρομολόγηση και ανάθεση μήκους κύματος σε οπτικά δίκτυα βασισμένη στα φυσικά χαρακτηριστικά του δικτύου

Μανουσάκης, Κωνσταντίνος

26 October 2007

Ο πιο σύγχρονος και περισσότερα υποσχόμενος τύπος οπτικών δικτύων, είναι τα οπτικά δίκτυα πολυπλεξίας διαίρεσης μήκους κύματος (Wavelength Division Multiplexing – WDM). Τα δίκτυα αυτά διαθέτουν τεράστια χωρητικότητα και αναμένεται να αποτελέσουν τα μελλοντικά δίκτυα κορμού για τη μεταφορά μεγάλου όγκου δεδομένων. Η πλήρης αξιοποίηση της χωρητικότητας των WDM δικτύων, όμως, απαιτεί την επίλυση ειδικών θεμάτων που σχετίζονται µε τις ιδιαιτερότητες και τη φύση των WDM οπτικών δικτύων. Το σημαντικότερο ίσως από αυτά είναι το πρόβλημα της δρομολόγησης και ανάθεσης μήκους κύματος (Routing and Wavelength Assignment – RWA), πάνω στο οποίο έχει αναπτυχθεί έντονη ερευνητική δραστηριότητα τα τελευταία χρόνια, το οποίο είναι NP-πλήρες. Ένα άλλο θέμα που χρήζει ιδιαίτερης προσοχής είναι οι εξασθενήσεις που υφίσταται ένα σήμα μέσα στο οπτικό δίκτυο. Όταν λοιπόν κάποιο σήμα διαδίδεται κατά μήκος ενός οπτικού μονοπατιού πέφτει η ποιότητα του εξαιτίας των φυσικών επιδράσεων που δέχεται. Οι φυσικές επιδράσεις κατά κανόνα μειώνουν τον λόγο σήματος προς θόρυβο (SNR), με αποτέλεσμα να αυξηθεί σημαντικά και η συχνότητα εμφάνισης λαθών (BER) στον κόμβο προορισμού. Αν η παραπάνω συχνότητα εμφάνισης λαθών είναι μεγαλύτερη από ένα καθορισμένο όριο, τότε το αίτημα δρομολόγησης θα πρέπει να απορριφθεί. Επομένως κατά την επίλυση του RWA προβλήματος θα πρέπει να ληφθούν υπόψη οι επιδράσεις που προκαλούνται στο σήμα λόγω των φυσικών χαρακτηριστικών του δικτύου. Στην παρούσα διπλωματική εργασία έχει υλοποιηθεί ένας αλγόριθμος για την επίλυση του στατικού RWA, που βασίζεται στην μοντελοποίηση ενός γραμμικού προβλήματος (Linear Programming – LP). Κατά την μοντελοποίηση λαμβάνονται υπόψη οι πιο σημαντικές επιδράσεις, όπως η χρωματική διασπορά (Chromatic Dispersion – CD), η διασπορά τρόπου πόλωσης (Polarization Mode Dispersion – PMD), η ενισχυμένη αυθόρμητη εκπομπή (Amplifier Spontaneous Emission – ASE) και η αλληλεπίδραση γειτονικών καναλιών (crosstalk). Η επίδραση των τριών πρώτων παραμέτρων εξαρτάται αποκλειστικά από τα χαρακτηριστικά των συνδέσμων και μοντελοποιούνται σύμφωνα με αναλυτικούς τύπους, ενώ η επίδραση του crosstalk εξαρτάται από τον αριθμό των οπτικών μονοπατιών που διατρέχουν ένα σύνδεσμο. Προτείνεται επίσης μία συνάρτηση βελτιστοποίησης ώστε να προκύπτουν ακέραιες λύσεις με πολύ μεγάλη πιθανότητα από την επίλυση του LP (Linear Program) προβλήματος. Αυτός ο αλγόριθμος εφαρμόζεται σε ένα μητροπολιτικό δίκτυο και λαμβάνονται συγκριτικά αποτελέσματα για διάφορες παραμέτρους των φυσικών στοιχείων του δικτύου. / Wavelength division multiplexing (WDM) is a promising technology for faster and more reliable data communication networks. In a WDM network several optical signals are sent on the same fiber using different wavelength channels. Multiple WDM channels from different end users may be multiplexed on the same fiber. Traditionally only a small fraction of the fiber capacity is in use, but by using WDM it is possible to exploit this huge capacity more efficiently. Under WDM, the optical transmission spectrum is curved up into a number of non-overlapping wavelength bands, with each wavelength supporting a single communication channel operating at whatever rate one desires. WDM technology has been recognized as one of the key components of the future networks. Routing and wavelength assignment (RWA) is a crucial issue for WDM optical network designers. In wavelength routed WDM optical networks connections between terminal stations are established through the use of lightpaths. Given a WDM optical topology and a set of connection requests between pairs of source-destination terminal nodes, the problem of how to route all the lightpaths simultaneously, one per connection, and which wavelength should be assigned to each one of them, subject to minimizing network resources or maximizing traffic characteristics, arises; this is known as the Routing and Wavelength Assignment problem RWA. In transparent networks, the signal quality is subject to a variety of physical impairments, such as polarization mode dispersion (PMD), amplified spontaneous emission (ASE) noise and chromatic dispersion (CD) and crosstalk. These impairments are linearly modeled and handled effectively by a set of analytical formulas as additional constraints on RWA. We apply our algorithm to perform impairment-constraint based RWA, in order to obtain comparative results of a typical metropolitan network's performance under various network and impairment parameters, such as bit rate, amplifier gain and type, modulation format used, etc.

Φυσικές εξασθενήσεις

LP Μοντελοποίηση

621.382 7

RWA

Routing and wavelength Assignment

Physical Impairments

LP formulation