Efficient Sensitivity Analysis and Design Optimization of Photonic Devices

Swillam, Mohamed A.

10 1900

Pages (41,133,161,209) were omitted from the thesis as they were completely blank pages. / <p> In this thesis, we propose efficient approaches for design optimization of passive and active photonic devices. These approaches are based on utilizing gradient based optimization algorithms for efficient optimization of photonic devices. Some of the proposed approaches obtain the required gradient (sensitivity) information efficiently using adjoint variable method (AVM) applied directly to the exploited numerical techniques. Other approaches are based on formulating the design problem as an optimization problem using convex programming. These approaches utilize the gradient-based interior point method (IPM) for solving the design.</p> <p> The AVM aims at efficiently obtaining the sensitivity information using the numerical technique. This technique requires a solution of an additional simulation of the adjoint system. The information obtained from the original and the adjoint simulation is sufficient to obtain the response and the sensitivity of the response with respect to all the design parameters. The AVM technique differs for different numerical method. </p> <p> The obtained sensitivity using the AVM approach is not only useful for exploiting gradient based optimization for design optimization, but also for yield and tolerance analyses of the newly proposed designs. </p> <p> We proposed a second order accurate approach to obtain the sensitivity information using finite difference time domain (FDTD) technique. This approach utilizes the AVM to efficiently obtain the sensitivity information. This approach is exploited for efficiently obtaining the sensitivity of the power reflectivity and coupling coefficient of various devices. This approach has been also utilized for obtaining the sensitivity of the dispersion characteristics of different guided wave structures.</p> <p> We also introduce a novel approach for sensitivity analysis of photonic devices using the beam propagation method (BPM). This approach is simple and easy to implement. It exploits the existing factorization of the system matrices for efficient calculation of the sensitivity of the required objective function. This approach is also utilized for sensitivity analysis of the vectorial modal properties of different guided wave structures. This approach is also exploited for sensitivity analysis of various surface plasmon devices. </p> <p> This AVM approach is also exploited to propose a novel design of an optical switch with wide working wavelength band and compact size. The switch is based on the self imaging theory in multimode waveguide with a refractive index has approximate parabolic profile. The design problem is formulated as two stage optimization procedure. The optimization algorithm exploits the efficiently obtained sensitivity information from a BPM simulation. The final design has interesting characteristics.</p> <p> An efficient approach is also proposed to obtain the sensitivity of the energy levels and wavefunctions of different quantum structures obtained using time dependent and time independent Schrodinger equation. This approach is exploited for design optimization of different quantum well lasers.</p> <p> We also propose a convex formulation for the design problem of multilayer optical coatings. This formulation allows for efficient design of structures with large number of layers in fractions of a second without an initial design.</p> / Thesis / Doctor of Philosophy (PhD)

Novel printing technologies for nanophotonic and nanoelectronic devices

Lin, Xiaohui, active 21st century

15 October 2014

As optical interconnects make their paces to replace traditional electrical interconnects, implementing low cost optical components and hybrid optic-electronic systems are of great interest. In the research work described in this dissertation, we are making our efforts to develop several practical optical components using novel printing technologies including imprinting, ink-jet printing and a combination of both. Imprinting process using low cost electroplating mold is investigated and applied to the waveguide molding process, and it greatly reduces the surface roughness and thus the optical propagation loss. The imprinting process can be applied to photonic components from multi-mode waveguides with 50[mu]m critical dimension down to photonic crystal structures with 500nm hole diameter. Compared to traditional lithography process, imprinting process is featured by its great repeatability and high yield to define patterns on existing layers. Furthermore we still need an approach to deposit layers and that is the reason we integrate the ink-jet printing technology, another low-cost, low material consumption, environmental friendly process. Ink-jet printing process is capable of depositing a wide range of materials, including conductive layer, dielectric layer or other functional layers with defined patterns. Together with molding technology, we demonstrate three applications: proximity coupler, thermo-optic (TO) switch and electro-optic (EO) polymer modulator. The proximity coupler uses imprinted 50[mu]m waveguide with embedded mirrors and ink-jet printed micro-lenses to improve the board-to-board optical interconnects quality. The TO switch and EO modulator both utilize imprinting technology to define a core pattern in the cladding layer. Ink-jet printing is used to deposit the core layer for TO switch and the electrode layers for EO modulator. The fabricated TO switch operates at 1 kHz with less than 0.5ms switching time and the EO modulator shows V[pi][middle dot]L=5.68V[middle dot]cm. To the best of our knowledge, these are the first demonstrations of functional optical switches and modulators using printing method. To further enable the high rate fabrication of ink-jet printed photonic and electronic devices with multiple layers on flexible substrate, we develop a roll-to-roll ink-jet printing system, from hardware integration to software implementation. Machine vision aided real time automatic registration is achieved when printing multiple layers. / text

Imprinting

Ink-jet printing

Polymer photonic devices

Photonic devices in solitonic waveguides

Alonzo, Massimo

07 May 2010

La thèse montre des solutions pour la réalisation de circuits photoniques intégrés utilisant le caractère volumétrique et les très faibles pertes en propagation des solitons spatiaux . On s'intéresse aux élément de base: interconnections, sources et router optique (comme dispositif d'élaboration). Interconnections et sources sont réalisé dans le niobat de lithium (LN) qui fournis des structures avec une très longe durée temporelle. Le fonctionnement d'un router optique est démontré dans le semiconducteur photorefractif (PR) InP:Fe en raison de sa sensitivité aux longueurs d'onde infrarouges (IR) et à son temps de réponse rapide. On montre que les pertes en propagation dans les interconnections solitoniques peuvent être réduites à nouveau en utilisant un faisceau en polarisation ordinaire qui augmente la variation d'indice de réfraction induite. La réalisation de sources intégrées solitoniques est étudié pour avoir émission en bleu à 400nm et en IR à 1530nm. Celles en bleu sont obtenues par génération de deuxième harmonique ; le rôle du bleu pour la formation des solitons est montré et ses propriété physiques étudiées. Celles en IR sont obtenues en dopant le LN avec des ions (actifs) d'erbium. Leurs effets sur les paramètres PR sont présentés et les solitons spatiaux sont obtenus en excitant l'absorption soit du LN soit de l'erbium. L'amplification de la luminescence est étudié numériquement. Le routage optique dans le InP :Fe est obtenu en faisant interagir deux solitons cohérents et en changeant leur phase relative. L'augmentation de la séparation ou leur fusion est analysé en fonctionne de la distance entre eux, température et intensité de la lumière.

[PHYS] Physics

photonic devices

solitonic waveguides

Modal Methods for Modeling and Simulation of Photonic

Mu, Jianwei

04 1900

Optical waveguide structures and devices are the fundamental basic building blocks of photonic cireuits which play important roles in modern telecommunication and sensing systems. With the fast development of fabrication technologies and in response to the needs of miniaturization and fast increased functionality in future integrated photonic chips, various structures based on high-index contrast waveguides, surface plasmonic polaritons structures, etc., have been widely proposed and investigated. Modeling and simulation methods, as efficient and excellent cost performance tools comparing to costly facilities and time-consuming fabrication procedures, are demanded to explore and design the devices and circuits before their finalization. This thesis covers a series of techniques for modeling, simulation and design of photonic devices and circuits with the emphasis of handling of radiation wave and the related power couplings. The fundamental issue in optical waveguide analysis is to obtain the complete mode spectrum. In principle, we need the radiation modes to expand the arbitrary fields of an open waveguide. In practice, however, the continuum nature of the radiation modes makes them hard to use. The discrete leaky modes may approximately represent a cluster of radiation modes under some circumstance and can be utilized in mode expansion together with guided modes to significantly simplify the analysis of mode coupling problems in optical waveguides. However, the leaky modes are unbounded by nature and hence lack the usual characteristics of normal guided modes in terms of normalization and orthogonality. Recently a novel scheme for handling of radiation optical fields was proposed and demonstrated by applying perfectly matching layers (PML) terminated with a perfectly reflecting boundary (PRB) condition. In this scheme, the radiation fields are represented in terms of a set of complex modes, some of which resemble the conventional leaky modes and others associated with the interaction between the PML media and the reflecting numerical boundaries. The mode spectrum is therefore split into the guided modes and complex modes which possess the normal mode features such as normalization and modal orthogonality. The seemingly paradoxical application of both the PML and PRB in the new method has in fact overcome one of the main challenges assoiated with this traditional method, i.e., the desire for discrete, orthogonal, and normalized modes to represent radiation fields and the need for elimination and reduction of spurious reflections from the edges of the finite computation window. With the understanding of mode spectrum, a full vector mode matching method and a complex coupled mode method for analyzing the wave propagation in optical waveguides under the framework of PRL and PRB computation model have been proposed. The methods have been validated through various structures such as waveguide facet, polarization rotators, long/short period gratings etc. Then the proposed techniques have been utilized to design a series of waveguide structures based on surface plasmonic polaritons, slot waveguides etc. / Thesis / Doctor of Philosophy (PhD)

Modal Methods

Modeling

Simulation

Photonic Devices

[en] DEVELOPMENT AND CHARACTERIZATION OF PHOTONIC DEVICES / [pt] DESENVOLVIMENTO E CARACTERIZAÇÃO DE DISPOSITIVOS FOTÔNICOS UTILIZANDO POLÍMEROS

LUCIENE DA SILVA DEMENICIS

17 August 2006

[pt] Polimeros orgânicos de natureza conjugada têm despertado bastante interessante como materiais ópticos não-lineares por serem extremamente promissores para o desenvolvimento de dispositivos fotônicos, como por exemplo dispositivos de comunicações. Além de possuírem resposta óptica não - linear intensa e rápida, seu modo de preparação e sua forma final apresentam grande flexibilidade. Do ponto de vista de aplicação, os parâmetros do material mais importantes são : a susceptibilidade não-linear de terceira ordem (x (3)) cuja parte real está relacionada com o índice de refração não-linear e a parte imaginária relacionada com o coeficiente de absorção não-linear; o tempo de resposta; o coeficiente de absorção linear no comprimento de onda de operação (alfa L); a capacidade de processamento; o limiar de dano e a estabilidade térmica. Dentre os polímeros conjugados, destaca-se a família dos politiofenos, compostos heterocíclicos de elevada estabilidade, que exibem interessantes propriedades de transporte e acentuada não-linearidade de terceira ordem. Neste trabalho as propriedades ópticas do politiofeno: X (3), partes real e imaginária; alfaL; e tempo de resposta, foram investigadas experimentalmente. A técnica utilizada para medida dos efeitos não-lineares de terceira ordem foi a técnica de Z-scan convencional. Os valores absolutos e s sinais do índice de refração não - linear e do coeficiente de absorção não-linear foram encontrados como sendo da ordem de - 10 -12 cm 2/W e - 10 - 8 cm/W, respectivamente. Para analisar os resultados experimentais foi necessário utilizar um tratamento teórico relativamente novo. Esta abordagem teórica é diferente da convencional e fornece resultados satisfatórios que descrevem bem os resultados experimentais. O tempo de resposta da não-linearidade do politiofeno foi obtido com a técnica de Z-scan resolvida no tempo, utilizando um único comprimento de onda e polarizações cruzadas. O valor obtido foi inferior à 100 os. Além de caracterizar o politiofeno, foi também demonstrada a utilização dexte polímero comoporta lógica E (AND)m através de uma medida envolvendo chaveamento Kerr. Este experimento mostrou que é possível realizar um chaveamento total óptico onde um feixe de luz é controlado por um outro feixe de luz, com duração de algumas dezenas de picossegundos. / [en] Conjugated organic polymers are of wide interest as nonlinear optical materials because of their potential applications in photonic devices, such as communication devices. They have a large and fast nonlinear optical response, as well as a great flexibility in their preparing method. For device applications, the most important parameters are: third-order optical nonlinear susceptibility X(3), which real part is related with nonlinear refractive index and imaginary part is related with nonlinear absorption coefficient; response time; absorptioon at operating wavelength alfaL; processability; damage threshold; and thermal stability. There are many conjugated polymers, and the polythiophene class, which includes high stabilityn heterocyclic compunds, is one of the most impoant because of its interesting transport properties and large third-order nonlinearity. In this work the optical properties of polythiophene: X (3), real and imaginary parts; alfaL and time response, were investigated experimentally. The Z-scan technique was used to measure the third-order nonlinear effects. The value and the sign of the nonlinear refractive index and nonlinear absorption coefficient of the polythiophene were found to be around -10 -12cm2/W and -10-8 cm/W, respectively. To analyze the experimental data it wass necessary to use a new theoretical approach. This approach is different from the conventional one and produces better fitting of the experimental results. The nonlinear response time of the polythiophene was measured using the time-resolved Z-scan technique, using a single waveguide and perpendicular polarizations. The time response is smaller than 100 ps. Besides the polythiophene characterization, it was demonstrated that this polymer can work like an AND logical gate using Kerr switching. This wxperiment showed that it is possible to make a fast (picoseconds) all- optical switch using a light beam to control another light beam.

[pt] POLIMERO

[en] POLYMER

[pt] DISPOSITIVOS FOTONICOS

[en] PHOTONIC DEVICES

Vertically-Integrated Photonic Devices in Silicon-on-Insulator

Brooks, Christopher

January 2010

Pages viii, xii, xiv, 32, 110, 182, 188, 194 were blank and therefore omitted. / <p> The functional density of photonic integrated circuits can be significantly increased by stacking multiple waveguide layers. These vertically-integrated devices require optical couplers to switch light signals between their layers. In this thesis, optical coupling between two stacked silicon-on-insulator slab waveguides has been demonstrated with a coupling efficiency of 68±4%, obtained with a coupler length of 3535 μm. The main advantage of using a silicon-based material system for photonic integrated circuits is its compatability with existing electronics manufacturing processes, facilitating cost-effective fabrication and the monolithic integration of both photonics and electronics on a single device. </p> <p> Coupling between more complex silicon-on-insulator waveguide structures with lateral confinement was then demonstrated. The coupling ratio between stacked silicon rib wavelengths was measured to be 54±4%, while ratios of 71±4% and 93±4% were obtained for stacked channel waveguide and multimode interferometer-based couplers respectively. The corresponding coupler lengths for these three designs were 572 μm, 690 μm and 241 μm respectively. The sensitivity of these couplers to the input wavelength and polarization state has also been evaluated. These vertical-integrated couplers, along with other structures, have been thoroughly simulated, including their tolerance to fabrication errors. Novel fabrication processes used to demonstrate coupling in proof-of-concept devices have been developed, including an in-house wafer bonding procedure. </p> / Thesis / Doctor of Philosophy (PhD)

engineering physics

vertically-integrated photonic devices

silicon-on-insulator

Broadband matching and distortion performance relating to multiple subcarrier multiplexed photonic systems

O'Brien, Daniel Gerard, n/a

January 1992

This thesis describes the outcome of study to investigate methods of broadband matching to photonic devices such as lasers and high speed detectors. The thesis is divided into two areas of interest relating to the design of broadband fiber optic links. The first area is the application of numerical methods and commensurate line methods to the design of compact equalisers which allow an improved transducer power gain over a wide band. It is shown that physically small equalisers can yield an improvement of 4 dB over a 2 GHz bandwidth. The second area considered is the distortion inherent in a laser diode. Detailed measurements of the second order and intermodulation products are given. A small signal perturbation analysis is presented which helps to explain the observed distortion products. The results of numerical simulation of the distortion using a state variable implementation of the full rate equations and related first, second and intermodulation equations is presented and possible methods of reducing the distortion are explored. It is shown that in principle the distortion could be reduced by pre-generating the distortion and adding an inverted form of the distortion to the transmitted signal. The distortion can then be corrected in the fiber and simulation studies suggest that an improvement of 13 dB optical or 26 dB electrical may be possible.

broadband matching

photonic devices

broadband fiber optic links

distortion performance

laser diodes

Dynamic Phase Filtering with Integrated Optical Ring Resonators

Adams, Donald Benjamin

2010 August 1900

Coherent optical signal processing systems typically require dynamic, low-loss phase changes of an optical signal. Waveform generation employing phase modulation is an important application area. In particular, laser radar systems have been shown to perform better with non-linear frequency chirps. This work shows how dynamically tunable integrated optical ring resonators are able to produce such phase changes to a signal in an effective manner and offer new possibilities for the detection of phase-modulated optical signals. When designing and fabricating dynamically tunable integrated optical ring resonators for any application, system level requirements must be taken into account. For frequency chirped laser radar systems, the primary system level requirements are good long range performance and fine range resolution. These mainly depend on the first sidelobe level and mainlobe width of the autocorrelation of the chirp. Through simulation, the sidelobe level and mainlobe width of the autocorrelation of the non-linear frequency modulated chirp generated by a series of integrated optical ring resonators is shown to be significantly lower than the well-known tangent-FM chirp. Proof-of-concept experimentation is also important to verify simulation assumptions. A proof-of-concept experiment employing thermally tunable Silicon-Nitride integrated optical ring resonators is shown to generate non-linear frequency modulated chirp waveforms with peak instantaneous frequencies of 28 kHz. Besides laser radar waveform generation, three other system level applications of dynamically tunable integrated optical ring resonators are explored in this work. A series of dynamically tunable integrated optical ring resonators is shown to produce constant dispersion which can then help extract complex spectral information. Broadband photonic RF phase shifting for beam steering of a phased array antenna is also shown using dynamically tunable integrated optical ring resonators. Finally all-optical pulse compression for laser radar using dynamically tunable integrated optical ring resonators is shown through simulation and proof-of-concept experimentation.

Phase Filtering

Integrated Photonic Devices

Optical Ring Resonators

LADAR

RF Photonics

Fabrication and characterization of ZnO nanostructures for sensing and photonic device applications

Ali, Syed M. Usman

January 2012

Nanotechnology is an emerging inter-disciplinary paradigm which encompasses diverse fields of science and engineering converge at the nanoscale. This nanoscale science and nanostructure engineering have well demonstrated in the fabrication of sensors/transducers devices with faster response time and better sensitivity then the planer version of the sensor’s configurations. Nanotechnology is not just to grow/fabricate nanostructures by just mixing nanoscale materials together but it requires the ability to understand and to precisely manipulate and control of the developed nanomaterials in a useful way. Nanotechnology is aiding to substantially improve, even revolutionize, many technology and industry sectors like information technology, energy, environmental science, medicine/medical instrumentation, homeland security, food safety, and transportation, among many others. Such applications of nanotechnology are delivering in both expected and unexpected ways on nanotechnology’s promise to benefit the society. The semiconductor ZnO with wide band gap (~ 3.37 eV) is a distinguish and unique material and its nanostructures have attracted great attention among the researchers due to its peculiar properties such as large exciton binding energy (60 meV) at room temperature, the high electron mobility, high thermal conductivity, good transparency and easiness of fabricating it in the different type of nanostructures. Based on all these fascinating properties, ZnO have been chosen as a suitable material for the fabrication of photonic, transducers/sensors, piezoelectric, transparent and spin electronics devices etc. The objective of the current study is to highlight the recent developments in materials and techniques for electrochemical sensing and hetrostructure light emitting diodes (LEDs) luminescence properties based on the different ZnO nanostructures. The sensor devices fabricated and characterized in the work were applied to determine and monitor the real changes of the chemical or biochemical species. We have successfully demonstrated the application of our fabricated devices as primary transducers/sensors for the determination of extracellular glucose and the glucose inside the human fat cells and frog cells using the potentiometric technique. Moreover, the fabricated ZnO based nanosensors have also been applied for the selective determination of uric acid, urea and metal ions successfully. This thesis relates specifically to zinc oxide nanostructure based electrochemical sensors and photonic device (LED) applications.

Nanotechnology

zinc oxide

nanowires/ nanorods

nanotubes

nanoporous/nanoflakes

Phase Change Materials for Optoelectronic Devices and Memories: Characterization and Implementation

Sevison, Gary A.

06 January 2022

No description available.

Optics

Phase Change Materials

PCMs

Photonics

GST

SLM

Spatial Light Modulator

Photonic Devices