Index to NASA Tech Briefs, 1975

This index contains abstracts and four indexes--subject, personal author, originating Center, and Tech Brief number--for 1975 Tech Briefs

Holoscopic 3D imaging and display technology: Camera/ processing/ display

This thesis was submitted for the award of Doctor of Philosophy and was awarded by Brunel University LondonHoloscopic 3D imaging “Integral imaging” was first proposed by Lippmann in 1908. It has become an attractive technique for creating full colour 3D scene that exists in space. It promotes a single camera aperture for recording spatial information of a real scene and it uses a regularly spaced microlens arrays to simulate the principle of Fly’s eye technique, which creates physical duplicates of light field “true 3D-imaging technique”. While stereoscopic and multiview 3D imaging systems which simulate human eye technique are widely available in the commercial market, holoscopic 3D imaging technology is still in the research phase. The aim of this research is to investigate spatial resolution of holoscopic 3D imaging and display technology, which includes holoscopic 3D camera, processing and display. Smart microlens array architecture is proposed that doubles spatial resolution of holoscopic 3D camera horizontally by trading horizontal and vertical resolutions. In particular, it overcomes unbalanced pixel aspect ratio of unidirectional holoscopic 3D images. In addition, omnidirectional holoscopic 3D computer graphics rendering techniques are proposed that simplify the rendering complexity and facilitate holoscopic 3D content generation. Holoscopic 3D image stitching algorithm is proposed that widens overall viewing angle of holoscopic 3D camera aperture and pre-processing of holoscopic 3D image filters are proposed for spatial data alignment and 3D image data processing. In addition, Dynamic hyperlinker tool is developed that offers interactive holoscopic 3D video content search-ability and browse-ability. Novel pixel mapping techniques are proposed that improves spatial resolution and visual definition in space. For instance, 4D-DSPM enhances 3D pixels per inch from 44 3D-PPIs to 176 3D-PPIs horizontally and achieves spatial resolution of 1365 × 384 3D-Pixels whereas the traditional spatial resolution is 341 × 1536 3D-Pixels. In addition distributed pixel mapping is proposed that improves quality of holoscopic 3D scene in space by creating RGB-colour channel elemental images

TOWARDS HIGH RESOLUTION ENDOSCOPIC OPTICAL COHERENCE TOMOGRAPHY FOR IMAGING INTERNAL ORGANS

Optical coherence tomography (OCT) is a light based interferometric imaging technique that can provide high resolution (5-20 µm at 1300 nm), depth resolved, images in real-time. With recent advances in portable low coherent light sources for OCT it is now possible to achieve ultrahigh axial resolutions (≤ 3 µm) by moving to shorter central wavelengths such as 800 nm while utilizing a broad spectral bandwidth. Our goal was to push ultrahigh resolution OCT technology to in vivo imaging of internal organs for endoscopic assessment of tissue microstructure. This dissertation is separated into technological developments and biomedical imaging studies. Technological developments in this dissertation included development of a high speed, ultrahigh resolution distal scanning catheter. This catheter was based upon a miniature DC micromotor capable of rotational velocities in excess of 100 rps, a diffractive compound lens design that minimized chromatic aberrations, and a mechanical assembly that limited field of view blockage to less than 7.5% and maintained an outer diameter of 1.78 mm (with plastic sheath). In conjunction with the algorithm described in chapter 4 to correct for non-uniform rotational distortion, the overall imaging system was capable of high quality endoscopic imaging of internal organs in vivo. Equipped with the ultrahigh resolution endoscopic OCT system, imaging was performed in small airways and colorectal cancer. Imaging results demonstrated the ability to directly visualization of microstructural details such as airway smooth muscle in the small airways representing a major step forward in pulmonary imaging. With the ability to visualize airway smooth muscle, morphological changes in COPD and related diseases can be further investigated. Additionally, longitudinal changes in an ETBF induced colon cancer model in APCMin mice were studied as well. Quantitative assessment of tissue microarchitecture was performed by measuring the attenuation coefficient to find a bimodal distribution separating normal healthy tissue from polyps. Finally, results from two additional projects were also demonstrated. Chapter 7 shows some results from vascular imaging in a tumor angiogenesis model and middle cerebral artery occlusion model. Chapter 8 describes an endoscopic multimodal OCT and fluorescence imaging platform with results in ex vivo rabbit esophagus

NASA Tech Briefs, November 2011

The topics include: 1) Flight Test Results from the Rake Airflow Gage Experiment on the F-15B; 2) Telemetry and Science Data Software System; 3) CropEx Web-Based Agricultural Monitoring and Decision Support; 4) High-Performance Data Analysis Tools for Sun-Earth Connection Missions; 5) Experiment in Onboard Synthetic Aperture Radar Data Processing; 6) Microfabrication of a High-Throughput Nanochannel Delivery/Filtration System; 7) Improved Design and Fabrication of Hydrated-Salt Pills; 8) Monolithic Flexure Pre-Stressed Ultrasonic Horns; 9) Cryogenic Quenching Process for Electronic Part Screening; 10) Broadband Via-Less Microwave Crossover Using Microstrip-CPW Transitions; 11) Wheel-Based Ice Sensors for Road Vehicles; 12) G-DYN Multibody Dynamics Engine; 13) Multibody Simulation Software Testbed for Small-Body Exploration and Sampling; 14) Propulsive Reaction Control System Model; 15) Licklider Transmission Protocol Implementation; 16) Core Recursive Hierarchical Image Segmentation; 17) Two-Stage Centrifugal Fan; 18) Combined Structural and Trajectory Control of Variable-Geometry Planetary Entry Systems; 19) Pressure Regulator With Internal Ejector Circulation Pump, Flow and Pressure Measurement Porting, and Fuel Cell System Integration Options; 20) Temperature-Sensitive Coating Sensor Based on Hematite; 21) Standardization of a Volumetric Displacement Measurement for Two-Body Abrasion Scratch Test Data Analysis; 22) Detection of Carbon Monoxide Using Polymer-Carbon Composite Films; 23) Substituted Quaternary Ammonium Salts Improve Low-Temperature Performance of Double-Layer Capacitors; 24) Sustainably Sourced, Thermally Resistant, Radiation Hard Biopolymer; 25) Integrated Lens Antennas for Multi-Pixel Receivers; 26) 180-GHz Interferometric Imager; 27) Maturation of Structural Health Management Systems for Solid Rocket Motors; 28) Validating Phasing and Geometry of Large Focal Plane Arrays; 29) Transverse Pupil Shifts for Adaptive Optics Non-Common Path Calibration; 30) Qualification of Fiber Optic Cables for Martian Extreme Temperature Environments; 31) Solid-State Spectral Light Source System; 32) Multiple-Event, Single-Photon Counting Imaging Sensor; 33) Surface Modeling to Support Small-Body Spacecraft Exploration and Proximity Operations; and 34) Achieving Exact and Constant Turnaround Ratio in a DDS-Based Coherent Transponder

Next generation Fourier ptychographic microscopy: computational and experimental techniques

Fourier ptychography is a recently developed computational imaging technique, which enables gigapixel image reconstruction from multiple low-resolution measurements. The technique can be implemented on simple, low-quality microscopes to achieve unprecedented image quality by exchanging optical design complexity with computational complexity. While developments have been made, demonstrations typically use well-calibrated, highperformance microscopes. Therefore, the real world performance and true benefits of(lowcost) Fourier ptychography still need to be demonstrated in out-of-lab environments where unforeseen problems are not unlikely. In this thesis, I will demonstrate how to utilise Fourier ptychography in a fast, robust and cheap manner. Two experimental prototypes will be introduced, one of them being an ultra-low-cost 3D printed microscope capable of wide-field sub-micron resolution imaging. Another prototype was built to demonstrate high-speed gigapixel imaging, capable of 100-megapixel, 1µm resolution image capture in under 3 seconds. Novel image formation models and their refinements were developed to correct the incomplete conventional model. These include partial coherence of the illumination, deviation from the plane-wave assumption, and spatially varying aberrations. Lastly, Experimental work was also heavily supplemented by novel calibration and reconstruction algorithms. Theoretical work outlined in this thesis enables the use of tilted, off-axis optical components, alleviating typically assumed parallel plane optical geometry. Optical precision requirements can also be relaxed due to novel robust calibration algorithms. As a result, low-cost 3D printed microscopes can be used

Snapshot spectral imaging using image replication and birefringent interferometry : principles and applications

This thesis explores the image-replicating imaging spectrometer (IRIS). This relatively recent invention is a two-dimensional, snapshot spectral-imaging technology, capable of recording the spectral and spatial data from a scene instantaneously. Whereas conventional spectral-imaging technologies require multiple detector frames to record the entire data set, IRIS is able to record the data set in a single frame, a capability which is useful for highly dynamic scenes. The IRIS concept and the design of IRIS systems are explained in detail, and constraints on the performance of IRIS are determined. Practical issue in the use of IRIS systems are identi ed and solutions are identi ed and appraised. Some applications of IRIS are also shown, demonstrating its viability as a spectral imaging technology. Novel aspects of this work include the re nement of the IRIS design, demonstration of a registration algorithm for IRIS, designs for achromatic Wollaston prisms, a comparison of the IRIS technology with conventional spectral imaging technologies, and the application of IRIS to practical problems.Engineering and Physical Sciences Research Council (EPSRC)Selex Galile

Conference on Binary Optics: An Opportunity for Technical Exchange

The papers herein were presented at the Conference on Binary Optics held in Huntsville, AL, February 23-25, 1993. The papers were presented according to subject as follows: modeling and design, fabrication, and applications. Invited papers and tutorial viewgraphs presented on these subjects are included

NASA Tech Briefs, September 2008

Topics covered include: Nanotip Carpets as Antireflection Surfaces; Nano-Engineered Catalysts for Direct Methanol Fuel Cells; Capillography of Mats of Nanofibers; Directed Growth of Carbon Nanotubes Across Gaps; High-Voltage, Asymmetric-Waveform Generator; Magic-T Junction Using Microstrip/Slotline Transitions; On-Wafer Measurement of a Silicon-Based CMOS VCO at 324 GHz; Group-III Nitride Field Emitters; HEMT Amplifiers and Equipment for their On-Wafer Testing; Thermal Spray Formation of Polymer Coatings; Improved Gas Filling and Sealing of an HC-PCF; Making More-Complex Molecules Using Superthermal Atom/Molecule Collisions; Nematic Cells for Digital Light Deflection; Improved Silica Aerogel Composite Materials; Microgravity, Mesh-Crawling Legged Robots; Advanced Active-Magnetic-Bearing Thrust- Measurement System; Thermally Actuated Hydraulic Pumps; A New, Highly Improved Two-Cycle Engine; Flexible Structural-Health-Monitoring Sheets; Alignment Pins for Assembling and Disassembling Structures; Purifying Nucleic Acids from Samples of Extremely Low Biomass; Adjustable-Viewing-Angle Endoscopic Tool for Skull Base and Brain Surgery; UV-Resistant Non-Spore-Forming Bacteria From Spacecraft-Assembly Facilities; Hard-X-Ray/Soft-Gamma-Ray Imaging Sensor Assembly for Astronomy; Simplified Modeling of Oxidation of Hydrocarbons; Near-Field Spectroscopy with Nanoparticles Deposited by AFM; Light Collimator and Monitor for a Spectroradiometer; Hyperspectral Fluorescence and Reflectance Imaging Instrument; Improving the Optical Quality Factor of the WGM Resonator; Ultra-Stable Beacon Source for Laboratory Testing of Optical Tracking; Transmissive Diffractive Optical Element Solar Concentrators; Delaying Trains of Short Light Pulses in WGM Resonators; Toward Better Modeling of Supercritical Turbulent Mixing; JPEG 2000 Encoding with Perceptual Distortion Control; Intelligent Integrated Health Management for a System of Systems; Delay Banking for Managing Air Traffic; and Spline-Based Smoothing of Airfoil Curvatures