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Near-field combination apertures for ultra-resolution optical storageTang, Shu-Guo January 2002 (has links)
This dissertation proposes and demonstrates an innovative technique for ultra-resolution data storage. An original idea that combines two near-field techniques, aperture probes and the solid immersion lens (SIL), is implemented through modeling, fabrication, testing, phase-change recording, and writing condition studies. In the modeling, a theory for illumination and signal detection is presented. The power transmission for different near-field transducers illuminated by a lens is calculated versus NA. In detection, the angular spectrum illustrates advantages of the combination aperture system. In addition, geometrical design considerations are discussed with the modeling. Nearly optimal designs for APSIL and Al aperture + SIL are presented for the illumination wavelength 488 rim. Fabrication techniques are developed for dielectric aperture + SIL, which is called APSIL, and Al aperture + SIL, respectively through modeling geometrical design. Both near-field transducers are tested by edge-scan experiments. Spot size and optical efficiency from the APSIL system are evaluated. APSIL is evaluated for high-density recording on a phase-change medium. Minimum mark size and the modulation transfer function (MTF) are obtained experimentally. Control of writing conditions for an APSIL system are investigated with respect to polarization, axial focus position and transverse beam alignment. Our study shows that the APSIL system achieves much higher optical efficiency than aperture probe systems as well as exhibits better resolution than SIL systems.
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Creation of a uniform circular illuminance distribution using faceted reflective NURBS surfacesDavenport, Thomas Lewis January 2002 (has links)
Non-Uniform-Rational-B-Spline (NURBS) surfaces were investigated as a tool for creating an incoherent uniform circular illuminance distribution on a target plane. Specifically, a superposition solution, employing faceted reflective surfaces was explored. The primary shape of the facets investigated was square, in spherical polar coordinates, mainly due to tiling concerns. An optimization procedure was the primary method for determining the NURBS variables for facet surfaces. For the case of a single square-facet that creates a uniform circular-illuminance distribution, a perfect solution using aim-ray defects proved difficult at best. However, the use of flux tubes in evaluating the illuminance yielded a highly uniform distribution with a very nearly circular shape. Superposition surface-point interpolation NURBS surfaces, constructed with this type of facet, were found to provide an excellent solution to the overall problem. Solutions of this type were shown to be more efficient than a standard algorithmic approach. NURBS surfaces provided excellent boundary control, and while often non-critical in single-aperture systems, boundary control was found to be very important for faceted systems. The techniques developed for creating uniform illuminance distributions with shapes different from the facet aperture were also applied to other problems: such as a square-facet to arcuate-illuminance pattern, and a circular-facet to a square-illuminance pattern.
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Non-null interferometer for measurement of transmitted aspheric wavefrontsGappinger, Robert Orvin January 2002 (has links)
In order to better facilitate the use of aspheres in optical design, metrology systems must become independent from the asphere under test. This requires testing in a non-null sense. Large aspheric departures and steep wavefront slopes must be detected by the metrology instrument. Sub-Nyquist interferometry (SNI) is one such method which has been shown to reconstruct large wavefront departures. Large departures generate high spatial frequency fringes, which must be detected by the interferometer. This requires the use of a sparse array sensor to capture the high spatial frequency fringe data. A custom detector for this purpose has been developed and tested over spatial frequencies up to 400 cycles/mm. Testing in a non-null manner causes the test and reference rays in the interferometer to follow different optical paths through the system. The errors generated by this difference are test part dependent and must be calibrated independently for each test piece. Lens design software can be used to perform reverse optimization of the interferometer and data. This process requires an accurate interferometer model and is sensitive to the relative weighting of the various merit function targets. An iterative reverse optimization process has been developed which eliminates the weighting sensitivity and improves the optimization efficiency. The implementation of reverse optimization in turn generates constraints on the interferometer design. The class of aspheres to be tested also influences the system design. These factors lead to constraints on lens parameters, system apertures, and component verification considerations. A Mach-Zehnder interferometer is designed which satisfies the requirements and is used to build a transmitted wavefront SNI system. Experiments on several test parts were performed to verify the iterative reverse optimization process and to extend the use of SNI to non-rotationally symmetric aspheric wavefronts. Wedge angles were measured to within 1.5 arcseconds, radii of curvature to 0.1% and wavefront departures of up to 200λ were characterized to λ/6 PV and λ/47 rms. The reverse optimization process was shown to successfully remove up to 25 of induced aberration from an aspheric measurement. The results indicate potential for application of the iterative method and its associated design constraints to new interferometers for aspheric testing.
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Fundamentals of the optical design of multiple aperture telescopes with wide fields of viewSabatke, Erin Marie January 2002 (has links)
This dissertation derives and demonstrates a new approach to the design of wide-field interferometric telescopes. The first part of this dissertation is a tutorial on multiple aperture systems. Design basics such as PSF and OTF, fill factors, resolution, and temporal coherence are investigated. We show that the perfect image for a multiple aperture system is the sum of an image from each aperture and a set of fringes from each pair of apertures. Four example systems are designed by applying the derived design rules. The first system is a rotationally-symmetric Paul system that is then segmented to make a four-aperture system. The low-order design rules in this system are shown to be automatically satisfied. The second system is an array of four afocal telescopes that share a three-mirror combining telescope. Fold flats are used in the inner two arms to satisfy the requirement that the axial pathlengths should match. Linear piston errors are eliminated by forcing the beam configuration into the combiner to be a scaled version of the afocal array. The angles of the fold flats are chosen to eliminate any constant tilt errors. As a third example, the design of a beam combiner for the Large Binocular telescope is explored. By applying the design rules, coherent imaging with a 1 arcminute field of view is achieved with just three reflections. Linear defocus errors appear, but are minimized by bringing the beams to focus as closely together as possible. The sine condition is satisfied for the axial rays so that the linear piston errors are zero. As a fourth example, a space telescope design is presented that utilizes a flat gossamer mirror technology. The system would consist of a primary array of flats, a shared secondary mirror, and a tertiary array with one mirror corresponding to each of the primary flats. Each branch of the system consists of a primary flat, the shared secondary, and a tertiary that brings the beam to the correct image point. The position of the tertiary is chosen to eliminate axial pathlength errors. The RMS wavefront error is calculated as a function of the system parameters. This gives an efficient method for exploring design space for the gossamer systems. The performance of a system of five flats is explored in this way. A few specific five-flat systems are modeled with full interferometric raytraces, and the results show good agreement with the Strehl values predicted by calculation of the RMS wavefront errors. (Abstract shortened by UMI.)
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Fabrication and characterization of erbium doped waveguide amplifiers and lasersMadasamy, Pratheepan January 2003 (has links)
Planar waveguide amplifiers and lasers were fabricated using Ag film ion exchange on Er³⁺/Yb³⁺ codoped phosphate glass. The performance of these amplifiers and lasers were studied and characterized. Silver film ion exchange process was thoroughly studied and a process suitable for fabrication of low loss waveguides on Er³⁺/Yb³⁺ codoped phosphate glass was developed. A transmission loss of 0.15 dB/cm was obtained in surface waveguides on phosphate glass. Planar waveguide amplifiers were fabricated on Er³⁺/Yb³⁺ codoped phosphate glass and characterized. A net gain of 7 dB in a sample of length 4.7 cm and gain/cm of 1.5 dB/cm were achieved. Single mode waveguide laser arrays pumped by single mode laser diodes were fabricated. Their performance was characterized in terms of the output power, spectrum of the laser, lasing wavelength dependence on the waveguide width and the relative intensity noise (RIN) of the laser. The tunability of the lasing wavelength to the desired wavelength, after waveguide fabrication, by annealing was demonstrated. A novel planar waveguide laser configuration for single-mode operation around 1550 nm using cost-effective multimode diode pumping was demonstrated. The laser was fabricated by Ag film ion exchange in a hybrid phosphate glass which has active and passive regions monolithically integrated in a single glass chip. Power of 54 mW at 1538 nm was measured from the single-mode output waveguide.
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Design and analysis of a snapshot imaging spectropolarimeterLocke, Ann M. January 2003 (has links)
The subject of this dissertation is the implementation of Computed Tomographic Imaging Channeled Spectropolarimetry (CTICS) in the design and analysis of a short wave infrared (SWIR) system with a 54 x 46 spatial resolution and 70 band spectral resolution from 1.25-1.99 μm for the purpose of object identification and classification. It is the first of its kind to provide imaging spectropolarimetry with no moving parts and snapshot capability. This spectropolarimeter has applications in many fields, such as mining, military reconnaissance, biomedical imaging, and astronomy. First, motivations are provided for building this unique imaging spectropolarimeter by discussing the current applications of such systems, the drawbacks of previous designs, and a review of some the current systems being used. A review of basic concepts on imaging systems, linear algebra, and polarimetry is given as an introduction into the technical details of the design of the system that follow. First, designing the Computed Tomography Imaging Spectrometer (CTIS) and then the channeled spectropolarimetry components. The fusion of these two techniques create the CTICS. An assembled version of the SWIR CTIS is calibrated and reconstructions of various objects demonstrate the capabilities of this portion of the system. The polarimetry components are added and a discussion follows on the method used to extract the new data. Two systems, a polarization state generator (PSG) and rotating retarder fixed analyzer (RRFA) system are built to verify the CTICS accuracy. The final assembled system is presented and testing results are shown. Error analysis on various sources of noise is done. To conclude, a novel sub-Nyquist sampling technique is demonstrated and future work is suggested on a reconstruction technique that will streamline the postprocessing of the images.
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Polarization phase-shifting point-diffraction interferometerNeal, Robert Mark January 2003 (has links)
A new instrument, the polarization phase-shifting point-diffraction interferometer (PPSPDI), is developed utilizing a birefringent pinhole plate. The interferometer uses polarization to separate the test and reference beams, interfering what begin as orthogonal polarization states. The instrument combines the robust nature of Linnik's original point-diffraction interferometer with the ability to phase-shift for interferogram analysis. The instrument is compact, simple to align, vibration insensitive and can phase-shift without moving parts or separate reference optics. This dissertation describes the theory, design, application and manufacturing considerations of the PPSPDI. The original PDI design is expanded to include polarization and phase-shifting. The discussion includes the properties of the birefringent material used as well as various fabrication methods used for creating the pinhole. A new model is developed to determine the quality of the diffracted reference wavefront from the pinhole as a function of pinhole size and aberrations of the test optic. The operation and performance of the interferometer are also presented along with a detailed error analysis and performance limits of the design.
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Integrated optical components using hybrid organic-inorganic materials prepared by sol-gel technologyMishechkin, Oleg January 2003 (has links)
A technological platform based on low-temperature hybrid sol-gel method for fabrication of optical waveguides and integrated optical components has been developed. The developed chemistry for doping incorporation in the host network provides a range of refractive indexes (1.444-1.51) critical for device optimization. A passivation method for improving long-term stability of organic-inorganic sol-gel material is reported. The degradation of waveguide loss over time due to moisture adsorption from the atmosphere is drastically suppressed by coating the material with a protective thin SiO2 film. The results indicate a long-term optical loss below 0.3 dB/cm for protected waveguides. The theory of multimode interference couplers employing self-imaging effect is described. A novel approach for design of high-performance MMI devices in low-contrast material is proposed. The design method is based on optimization of refractive index contrast and width of a multimode waveguide (the body of MMI couplers) to achieve a maximum number of constructively interfering modes resulting to the best self-imaging. This optimization is carried out using 3D BPM simulations. This method was applied to design 1 x 4, 1 x 12, and 4 x 4 MMI couplers and led to a superior performance in excess loss, power imbalance in output ports, and polarization sensitivity. Taking advantage of the inherent input-output phase relations in a 4 x 4 MMI coupler, an optical 90° hybrid is realized by incorporation a Y-junction to coherently excite two ports of the coupler. A series of MMI couplers were fabricated and characterized. The experimental results are in good agreement with the design. Measured performance of the sol-gel derived MMI components was compared to analogues fabricated by other technologies. The comparison demonstrates the superior performance of the sol-gel devices. The polarization sensitivity of all fabricated couplers is below 0.05 dB.
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Erbium-doped tellurite glass microsphere amplifiers and lasersPeng, Xiang January 2004 (has links)
Due to the properties of extremely high quality factor and small mode volume, microsphere resonators have attracted considerable attention for signal processing, fiber communication and photon computation applications. This research work studies the optical properties of microsphere amplifier and laser. The Er³⁺-doped tellurite glass was examined, including emission cross-section, absorption cross-section and lifetime analysis. McCumber and Judd-Ofelt theories were used for theoretical calculations. Whispering gallery modes in the microsphere were calculated by using the measured parameters. Signal enhancement was obtained in this Er³⁺-doped tellurite glass microsphere. The enhancement of this Er³⁺-doped tellurite glass microsphere exceeds 12dB. Besides, the mode in a single mode tapered fiber was analyzed. Theoretical analysis was also performed to optimize the coupling scheme. We also analyzed the lasing characteristics of microsphere laser, including threshold, lasing wavelength, output power optimization, and temperature dependence. Theoretical calculations for these properties were also presented. State-of-the-art L-band microsphere laser with maximum output power of 124.5 μW was demonstrated which has potential in various photonic applications.
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System and material aspects of volumetric bit-wise optical data storageZhang, Yan January 2004 (has links)
There are several primary factors that limit the data capacity of a volumetric bit-wise optical data storage system. Firstly, the data density in each layer is limited by the spot size formed at the focus of the objective lens. The spherical aberration induced by the medium also limits the maximum depth that an optical system can reach with diffraction limited focus. A second primary factor is the undesired detection of data from layers other than the layer at the laser focus, which is an effect called inter-layer crosstalk. In the last, the transmission and the reflection rate of the medium sets the limit of the number of the data layers for a given laser diode. In the modeling, the inter-layer crosstalk of volumetric bit-wise storage systems is simulated by using three methods. Several far-field and near-field systems with spherical aberration compensators are presented. In addition, the maximum surface densities of these systems are discussed. A dynamic test stand equipped with a tracking servo is built for testing the fluorescent material performance in a simulated space environment. Coupon samples made of Super-Rens material are tested in another dynamic test stand equipped with a focus servo. Controls of writing conditions for Super-Rens material are investigated with respect to the focus spot speed and data rate. Overall, this dissertation provides a description of volumetric bit-wise optical data storage technology, in terms of the system and material aspects, through simulation and experiments.
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