TPF-I SWG Report - Exoplanet Exploration Program - NASA

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C HAPTER 6 6.5.2 Achromatic Nulling Testbed Gappinger, R. O., Wallace, J. K., Bartos, R. D., Macdonald, D. R., Brown, K. A., “Current progress on TPF-I nulling architectures at Jet Propulsion Laboratory,” in Techniques and Instrumentation for Detection of Exoplanets II, Proc. SPIE 5905, edited by D. R. Coulter, 55–61 (2005). Wallace, J. K., Babtiwale, V., Bartos, R., Brown, K., Gappinger, R., Loya, F., MacDonald, D., Martin, S., Negron, J., Truong, T., Vasisht, G., “Mid-IR interferometric nulling for TPF,” New Frontiers in Stellar Interferometry, Proc. SPIE 5491, edited by W. A. Traub, 862–873 (2004). Wallace, J. K., Bartos, R., Gappinger, R., F. Loya, S. Moser, J. Negron, “Progress in broadband infrared nulling technology for TPF,” in Techniques and Instrumentation for Detection of Exoplanets II, Proc. SPIE 5905, edited by D. R. Coulter, 47–54 (2005). 6.5.3 Planet Detection Testbed Martin, S., “TPF Planet Detection Testbed: a four beam infrared testbed demonstrating deep, stable nulling and planet detection,” 2005 IEEE Aerospace Conference, Big Sky, Montana (2005) Martin, S., “Progress in four-beam nulling: results from the Terrestrial Planet Finder Planet Detection Testbed,” 2006 IEEE Aerospace Conference, Big Sky, Montana, 4–11 March (2006). Martin, S., Szwaykowski, P., and Loya, F., “Testing exo-planet signal extraction using the Terrestrial Planet Finder planet detection testbed,” Techniques and Instrumentation for Detection of Exoplanets II, Proc. SPIE 5905, edited by D. R. Coulter, 70–79 (2005). Martin, S. R., Szwaykowski, P., Loya, F. M., and Liewer, K., “Progress in testing exo-planet signal extraction on the TPF-I Planet Detection Testbed,” Advances in Stellar Interferometry, Proc. SPIE 6268, edited by J. D. Monnier, M. Schöller, W. C. Danchi, 626818 (2006). 6.5.4 Adaptive Nuller Testbed Lay, O. P., Jeganathan, M., Peters, R., “Adaptive nulling: a new enabling technology for interferometric exo-planet detection,” Techniques and Instrumentation for Detection of Exoplanets, Proc. SPIE 5170, edited by D. R. Coulter, 103–112 (2003). Peters, R. D., Hirai, A., Jeganathan, M. Lay, O. P., “Near-IR demonstration of adaptive nuller based on deformable mirror,” New Frontiers in Stellar Interferometry, Proc. SPIE 5491, edited by W. A. Traub, 1630–1638 (2004). Peters, R. D., Hirai, A., Jeganathan, M., Lay, O. P., “Adaptive nulling with a deformable mirror in the near-IR,” Techniques and Instrumentation for Detection of Exoplanets II, Proc. SPIE 5905, edited by D. R. Coulter, 62–69 (2005). Peters, R. D., Lay, O. P., Hirai, A. Jeganathan, M., “Adaptive nulling for the Terrestrial Planet Finder Interferometer,” Advances in Stellar Interferometry, Proc. SPIE 6268, edited by J. D. Monnier, M. Schöller, W. C. Danchi, 62681C (2006). 156
T E C H N O L O G Y R OADMAP FOR TPF-I 6.5.5 Mid-Infrared Single Mode Spatial Filters Aggarwal, D., Shaw, L. B., and Sanghera, J., “Chalcogenide glass for mid- and longwave IR fiber lasers,” Fiber Lasers II: Technology, Systems, and Applications, edited by A. J. W. Brown, J. Nilsson, Proc. SPIE 5709, 242–248 (2005). Bordé, P., Perrin, G., Amy-Klein, A., Daussy, C., and Mazé, G., “Updated results on prototype Chalcogenide fibers for 10 micron wavefront spatial filtering,” Towards Other Earths: Darwin/TPF and the Search for Extrasolar Terrestrial Planets, edited by M. Fridlund and T. Henning, ESA SP 539, European Space Agency, Noordwijk, The Netherlands, pp. 371–374 (2003). Ksendzov, A., Bloemhof, E,. White, V., Wallace, J. K., Gappinger, R. O., Sanghera, J. S., Busse, L. E., Kim, W. J., Pureza, P. C., Nguyen, V. Q., Aggarwal, I. D., Shalem, S., and Katzir, A., “Measurement of spatial filtering capabilities of single mode infrared fibers,” Advances in Stellar Interferometry, edited by J. D. Monnier, M. Schöller, W. C. Danchi, Proc. SPIE 6268, 626838 (2006). Shalem, S., Tsun, A., Rave, E., Millo, A., Nagli, L., Katzir A., “Silver halide single-mode fibers for the middle infrared,” Appl. Phys. Lett. 87, 09113 (2005). 6.5.6 Future Hardware for General Astrophysics Beckers, J. M., “Field of view considerations for telescope arrays,” Advanced Technology Optical Telescopes III, Proc. SPIE 628, edited by L. D. Barr, 255–260 (1986). Colavita, M. M., et al. “The Palomar Testbed Interferometer,” Astrophys. J. 510, 505–521 (1999). Lardière, O., et al. “VIDA (Vlti Imaging with a Densified Array), a densified pupil combiner proposed for snapshot imaging with the VLTI,” Interferometry for Optical Astronomy II, Proc SPIE 4838, edited by W. A. Traub, 1018–1027 (2003). Leisawitz, D. et al., “Scientific motivation and technology requirements for the SPIRIT and SPECS farinfrared/submillimeter space interferometers,” UV, Optical, and IR Space Telescopes and Instruments, Proc. SPIE 4013, edited by J. B. Breckinridge and P. Jakobsen, 36–46 (2000). Leisawitz, D., Frey, B. D., Leviton, D. B., et al., “Wide-field imaging interferometry testbed I: purpose, testbed design, data, and synthesis algorithms,” Proc. SPIE 4852, 255–267 (2003). Mariotti, J.-M, and Ridgway, S. T., “Double Fourier spatio-spectral interferometry,” Astron. Astrophys. 195, 350–363 (1988). Martin, S., “The flight instrument design for the Terrestrial Planet Finder Interferometer,” Techniques and Instrumentation for Detection of Exoplanets II, Proc. SPIE 5905, edited by D. R. Coulter, 21–35 (2005). 157
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JPL Publication 07-1 Terrestrial Pl
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Abstract Over the past two years, t
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Acknowledgements Twenty-two represe
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Table of Contents 1 Introduction...
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4.8.3 Post-Nulling Calibration.....
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6.4.5 Double Fourier Interferometry
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I NTRODUCTION 1 Introduction Over 2
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I NTRODUCTION et al. 2004), and res
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I NTRODUCTION Standard Interferomet
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I NTRODUCTION 1.4 References Angel,
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C HAPTER 2 0.7 to 1.5 AU scaled by
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C HAPTER 2 Table 2-2. Illustrative
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C HAPTER 2 Classical interferometry
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C HAPTER 2 trivial in the absence o
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C HAPTER 2 Figure 2-3. Simulated mi
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C HAPTER 2 would be in atmospheres
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C HAPTER 2 Figure 2-6. The mid-infr
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C HAPTER 2 Lines of constant stella
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C HAPTER 2 presence of zodiacal clo
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C HAPTER 2 S EZ 2π ∫ θ max ∫
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C HAPTER 2 Figure 2-11. Observation
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C HAPTER 2 Figure 2-12. Models of t
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C HAPTER 2 Beichman, C. A., Fridlun
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C HAPTER 2 2.7.4 Suitable Targets E
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C HAPTER 2 Reach, W. T., Franz, B.
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C HAPTER 3 3.1.1 Darwin/TPF-I Prope
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C HAPTER 3 clouds or an OB associat
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C HAPTER 3 Figure 3-3. Three possib
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C HAPTER 3 the circumstellar disk,
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C HAPTER 3 Figure 3-6. (Left panel)
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C HAPTER 3 Continuum interferometry
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C HAPTER 3 Figure 3-9: Simulated im
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C HAPTER 3 3.3 Conclusions Darwin/T
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C HAPTER 3 Nguyen, H. T., Kallivaya
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D ESIGN AND A R C H I T E C T U R E
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C HAPTER 5 Heavy launch vehicle. Th
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C HAPTER 5 5.3.2 Combiner Spacecraf
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C HAPTER 5 5.3.5 Beam Transfer betw
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Page 130 and 131: C HAPTER 5 secondary mirror along t
Page 132 and 133: C HAPTER 5 a) c) b) d) IWA = 43 mas
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Page 138 and 139: C HAPTER 5 5.8.4 Angular Resolution
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Page 142 and 143: C HAPTER 5 The optimization works b
Page 145 and 146: T E C H N O L O G Y R OADMAP FOR TP
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Page 173 and 174: F UTURE D EVELOPMENTS 7 Preparatory
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Page 179 and 180: D ISCUSSION AND C ONCLUSION 8 Discu
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Page 183 and 184: T E C H N O L O G Y A DVISORY C O M
Page 185 and 186: F L I G H T S YSTEM C ONFIGURATION
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Page 208 and 209: A PPENDIX E Appendix E TPF-I Review
Page 210 and 211: A PPENDIX F Alice Quillen, Universi
Page 212: A PPENDIX F Figure 3-1 - Original f
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