| | Tuesday – November 14th, 2017
Mirror Tech/ SBIR/ STTR Workshop 2017 | |
| # | Presenter | Title | Org |
| | Government Technology Needs (OPEN) | |
| 00 | Stahl | NASA Welcome | NASA |
| 01 | Grant | Collaborative Opportunities within NASA’s STMD Portfolio | NASA |
| 02 | Thronson | NASA’s Physics of The Cosmos and Cosmic Origins Program Office: Investments to Enable Future NASA Strategic Astrophysics Missions | NASA |
| 03 | Crill | Technology Needs for Exoplanet Exploration Program | JPL |
| 04 | Bolcar | Technology Needs for LUVOIR | NASA |
| 05 | Dipirro | Technology Needs for OST | NASA |
| | SBIR Workshop (OPEN) | |
| 06 | Lewis | Post-Reauthorization SBIR Technology Infusion and Commercialization | JPL |
| 07 | Shaklan | SBIR Topic S2: Advanced Telescope Systems | JPL |
| 08 | Stahl | SBIR Subtopic S2.03 Advanced Optical Systems and Fabrication/Testing/Control Technologies for EUV/Optical and IR Telescope overview | NASA |
| 09 | Shiri | SBIR Subtopic S2.03 Advanced Optical Systems and Fabrication/Testing/Control Technologies for EUV/Optical and IR Telescope overview | NASA |
| | OPEN TECHNOLOGY SESSIONS | |
| | Additive Manufacturing Mirror Technology (OPEN) | |
| 10 | Kashalikar | Amorphous Si claddings are deposited at low temperature | Surmet |
| 11 | Carnahan | Optical and Infrared absorbance of nanotube based, optical black coatings and paints | NanoLab |
| 12 | Walker | EELT Prototype Mirror Segments and Beyond – Large Optics and Automation | Zeeko;
U-Huddersfield |
| | OPEN TECHNOLOGY SESSIONS | |
| | Additive Manufacturing Mirror Technology (OPEN) | |
| 13 | Casstevens | Additive Manufactured Very Light Weight Diamond Turned Aspheric Mirror | DOS |
| 14 | Goodman | 3D Printed Silicon Carbide Scalable to Meter-Class Segments for Far-IR | Goodman Tech |
| 15 | Harrison | Additively Manufactured, Thermally Stable Telescope Mirror Substrates | ASTS |
| 16 | Schaedler | Additive manufacturing of polymer derived ceramics | HRL |
| | Mirror Technology (OPEN) | |
| 17 | Lumpkins | Silica-Silica Mirror Substrate Fabrication Technology | Mentis |
| 18 | Easter | Large-Scale, Low Cost, Molded SiOC Mirror Component | Semplastics |
| 19 | Hardesty | Matching NiP on Be-38Al for Low Temp Mirrors | Peregrine |
| | Optical Metrology Technology (OPEN) | |
| 20 | Matthews | Developments in Non-Contact Metrology and Data Analytics | Optipro |
| 21 | North-Morris | High Speed Interferometry for Evaluating the Vibrational Response of Mounted JWST Segments | 4D |
| 22 | Olczak | PHAST: Phased Holographic Aspheric Stitching Technique | Harris |
| 23 | Markov | Rendering of Spatio-Temporal Dynamic of Deformable Mirrors | AS&T Inc. |
| | Wednesday – November 15th, 2017
Stable Telescope Technology (OPEN) | |
| 24 | Livas | Optical Telescope for the LISA Gravitational Wave Observatory | NASA |
| 25 | Saif | Ultra-Stable Structures: Develop & Character using Spatial Dynamic Metrology | NASA |
| 26 | Hardesty | Advanced Athermal Telescopes | Peregrine |
| 27 | Han | Optical characterization of 300 mm SiC mirrors due to thermal variatinos | KASI |
| 28 | Monroe | New Developments in Allvar Alloys | Allvar |
| 29 | Fischer | Ultra-Stable Zero-CTE HoneySiC and H2CMN Mirror Support Structures | ASCM |
| 30 | Catanzaro | Lightweight, Stable Optical Benches in Silicon Carbide and Beryllium | CFE |
| | Telescope & Instrumentation Technology (OPEN) | |
| | Free-Form Optics (OPEN) | |
| 31 | Conkey | Freeform Optics for Optical Payloads with Reduced Size and Weight | Voxtel |
| 32 | Bauer | Analyzing Aberration Fields of Three-mirror Telescope and Correcting them Using Freeform Zernike Surfaces | UoR |
| 33 | Papa | Four-Mirror Freeform Design | UoR |
| 34 | Horvath | Optomechanical Design and Fabrication of a Snap Together Freeform TMA Telescope | UNCC |
| Poster | Matthews | Freeform Manufacturing | CFEOtipro |
| 35 | Catanzaro | STOP modeling and Wavefront Sense / Control In support of GHAPS | CFE |
| 36 | Myer | Developments of Fully Monolithic Freeform Telescopes | Optimax |
| 37 | Menon | Combining machine learning, computation & micro-optics to enable reduced SWAP multi-spectral imaging systems | UoUT |
| | X-Ray Technology (OPEN) | |
| 38 | Young | Manufacturing Optics for the Imaging X-ray Polarimeter Explorer (IXPE) Mission | NASA |
| 39 | Ponsor | Pre-collimator Chemical Milling for X-ray Telescopes | Mindrum |
| 40 | Tyurina | BeatMark Software to reduce the cost of X-Ray mirror fabrication | Second Star Algonumerix |
| | HabEx (OPEN) | |
| 41 | Stahl | HabEx Telescope Structural Design & Performance Prediction | NASA |
| | Coating Technology (OPEN) | |
| 42 | Quijada | Improving LUVOIR FUV instrument capabilities through enhanced coatings | NASA |
| 43 | Sheikh | Battery-powered process for coating telescope mirrors in space | Zecoat |
| 44 | Broadway | In-situ stress measurement of single and multilayer thin-films for x-ray optics. | NASA |
| 45 | Kennel | Pyramid Nanostructured Coatings for Stray Light Suppression | Applied Sci |
| 46 | Vijayraghavan | Proximity Glare Suppression for Astronomical Coronagraphy | Nanohmics |
| 47 | Hamilton | Intelligent Mirror Geometry for Detection, Power Production, Imaging | Sun Synchrony |
| | Thursday – November 16th, 2017
Exoplanet Exploration Program (ExEP) Technology (OPEN) | |
| 48 | Trauger | WFIRST Coronagraph Instrument (CGI) Update | JPL |
| 49 | Helmbrecht | MEMS Deformable Mirror Development at Iris AO | Iris AO |
| 50 | Bierden | MEMS Deformable Mirrors | Boston MM |
| 51 | Ziemer | Starshade Technology Activity | JPL |
| 52 | Harness | Starshade Subscale Testing/Model Validation | Princeton U |
| 53 | Hamilton | Starshade Contamination Control with First Contact Polymers | PCT |
| | Telescope Architectures (OPEN) | |
| 54 | Mukkerjee | In-space Assembly of Large Telescopes for Exoplanet Direct Imaging | JPL |
| 55 | MacEwen | Future Assembly and Servicing of Space Telescopes | Reviresco |
| 56 | Coppejans | DOMinATE a Deployable Vis-IR Optical MembrAne Telescope concept | Northwestern |
| 57 | Young | Probe Of Extreme Multi-Messenger Astrophysics (POEMMA) Instrument and Mission details | NASA |
| | Active Control Technology (OPEN) | |
| 58 | Shelton | Next-Generation Deformable Mirrors for Astronomical Coronagraphy by Utilizing PMN-PT Single Crystal Stack Actuators in integration with Driver ASIC | Microscale |
| | ITAR TECHNOLOGY SESSIONS | |
| | AMTD (ITAR) | |
| 59 | Stahl | AMTD Final Results | NASA |
| 60 | Mooney | AMTD-2: Stacked Core ULE® Mirror | Harris |
| 61 | Eng | 1.5-m ULE® Cryo & Mechanical Test Results | NASA |
| 62 | Brooks | Computed Tomography and Stiction in a Low Temperature Slumped Mirror | NASA |
| | Mirror Technology (ITAR) | |
| 63 | Dunn | Primary Mirror Fabrication for Rotating Synthetic Aperture (RSA) Imaging | UTAS |
| 64 | Southard | 3D Printing of Ultra-Low Expansion (ULE®) Glass | UTAS |
| 65 | Mooney | Advanced Mirror Construction – ULE® Replication | Harris |
| | JWST (ITAR) | |
| 66 | Feinberg | OTE/ISIM Integration and Test Summary | NASA |
| 67 | Keski-Kuha | Ambient Center of Curvature Testing | BATC |
| 68 | Daly | OTIS Ambient I&T | Harris |
| 69 | Texter | Deployment Tests and Results | NGST |
| 70 | Wells | JWST Primary Mirror Cryogenic Phasing and Performance Testing at JSC | Harris |
| 71 | Knight | Early Cryo-Optical Test Results | BATC |
| 72 | Wells | Early Cryo-Photogrammetry Results | Harris |
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