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References

1 Ackermann, M. et al. (Fermi Collaboration), “The Imprint of the Extragalactic Background Light in the Gamma-Ray Spectra of Blazars”, Science, 338, 1190 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1211.1671].
2 Ade, P. A. R. et al. (Planck Collaboration), “Planck 2013 results. XVI. Cosmological parameters”, Astron. Astrophys., 571, A16 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1303.5076].
3 Alves, D. R., “A review of the distance and structure of the Large Magellanic Cloud”, New Astron. Rev., 48, 659–665 (2004). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0310673].
4 Amendola, L. et al., “Cosmology and Fundamental Physics with the Euclid Satellite”, Living Rev. Relativity, 16, lrr-2013-6 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1206.1225 [astro-ph.CO]]. URL (accessed 7 August 2014):
http://www.livingreviews.org/lrr-2013-6.
5 An, D., Terndrup, D. M., Pinsonneault, M. H., Paulson, D. B., Hanson, R. B. and Stauffer, J. R., “The Distances to Open Clusters from Main-Sequence Fitting. III. Improved Accuracy with Empirically Calibrated Isochrones”, Astrophys. J., 655, 233–260 (2007). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0607549].
6 Anderson, L. et al., “The clustering of galaxies in the SDSS-III Baryon Oscillation Spectroscopic Survey: baryon acoustic oscillations in the Data Release 9 spectroscopic galaxy sample”, Mon. Not. R. Astron. Soc., 427, 3435–3467 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1203.6594].
7 Baade, W., “The Period-Luminosity Relation of the Cepheids”, Publ. Astron. Soc. Pac., 68, 5–16 (1956). [External LinkDOI], [External LinkADS].
8 Barbon, R., Ciatti, F. and Rosino, L., “Light curves and characteristics of recent supernovae”, Astron. Astrophys., 29, 57–67 (1973). [External LinkADS].
9 Barnes, T. G. and Evans, D. S., “Stellar angular diameters and visual surface brightness. I. Late spectral types”, Mon. Not. R. Astron. Soc., 174, 489–502 (1976). [External LinkADS].
10 Barnes, T. G., Jefferys, W. H., Berger, J. O., Mueller, P. J., Orr, K. and Rodriguez, R., “A Bayesian Analysis of the Cepheid Distance Scale”, Astrophys. J., 592, 539–554 (2003). [External LinkDOI], [External LinkADS].
11 Barrau, A., Gorecki, A. and Grain, J., “An original constraint on the Hubble constant: h > 0.74”, Mon. Not. R. Astron. Soc., 389, 919 (2008). [External LinkDOI].
12 Behr, A., “Zur Entfernungsskala der extragalaktischen Nebel”, Astron. Nachr., 279, 97 (1951). [External LinkDOI], [External LinkADS].
13 Benedict, G. F. et al., “Astrometry with the Hubble Space Telescope: A Parallax of the Fundamental Distance Calibrator delta Cephei”, Astron. J., 124, 1695–1705 (2002). [External LinkADS].
14 Benedict, G. F. et al., “Hubble Space Telescope Fine Guidance Sensor Parallaxes of Galactic Cepheid Variable Stars: Period-Luminosity Relations”, Astron. J., 133, 1810–1827 (2007). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0612465].
15 Beutler, F. et al., “The 6dF Galaxy Survey: Baryon Acoustic Oscillations and the local Hubble Constant”, Mon. Not. R. Astron. Soc., 416, 3017 (2011). [External LinkDOI].
16 Biggs, A. D., Browne, I. W. A., Helbig, P., Koopmans, L. V. E., Wilkinson, P. N. and Perley, R. A., “Time delay for the gravitational lens system B0218+357”, Mon. Not. R. Astron. Soc., 304, 349–358 (1999). [External LinkDOI], [External LinkADS], [External Linkastro-ph/9811282].
17 Biggs, A. D., Browne, I. W. A., Muxlow, T. W. B. and Wilkinson, P. N., “MERLIN/VLA imaging of the gravitational lens system B0218+357”, Mon. Not. R. Astron. Soc., 322, 821–826 (2001). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0011142].
18 Birkinshaw, M., “The Sunyaev–Zel’dovich effect”, Phys. Rep., 310, 97–195 (1999). [External LinkDOI], [External LinkADS].
19 Blake, C. et al., “The WiggleZ Dark Energy Survey: mapping the distance-redshift relation with baryon acoustic oscillations”, Mon. Not. R. Astron. Soc., 418, 1707–1724 (2011). [External LinkDOI], [External LinkADS], [External LinkarXiv:1108.2635].
20 Bolton, A. S. and Burles, S., “Prospects for the Determination of H0 through Observation of Multiply Imaged Supernovae in Galaxy Cluster Fields”, Astrophys. J., 592, 17–23 (2003). [External LinkDOI], [External LinkADS].
21 Bolton, A. S., Burles, S., Koopmans, L. V. E., Treu, T. and Moustakas, L. A., “The Sloan Lens ACS Survey. I. A Large Spectroscopically Selected Sample of Massive Early-Type Lens Galaxies”, Astrophys. J., 638, 703–724 (2006). [External LinkDOI], [External LinkADS].
22 Bonamente, M., Joy, M. K., LaRoque, S. J., Carlstrom, J. E., Reese, E. D. and Dawson, K. S., “Determination of the Cosmic Distance Scale from Sunyaev–Zel’dovich Effect and Chandra X-Ray Measurements of High-Redshift Galaxy Clusters”, Astrophys. J., 647, 25–54 (2006). [External LinkDOI], [External LinkADS].
23 Bonanos, A. Z. et al., “The First DIRECT Distance Determination to a Detached Eclipsing Binary in M33”, Astrophys. J., 652, 313–322 (2006). [External LinkDOI].
24 Braatz, J. et al., “Measuring the Hubble constant with observations of water-vapor megamasers”, in de Grijs, R., ed., Advancing the Physics of Cosmic Distances, Proceedings of IAU Symposium 289, August 2012, Proc. IAU, 289, pp. 255–261, (Cambridge University Press, Cambridge, 2013). [External LinkDOI], [External LinkADS].
25 Braatz, J. A., Reid, M. J., Humphreys, E. M. L., Henkel, C., Condon, J. J. and Lo, K. Y., “The Megamaser Cosmology Project. II. The Angular-diameter Distance to UGC 3789”, Astrophys. J., 718, 657–665 (2010). [External LinkDOI], [External LinkADS], [External LinkarXiv:1005.1955].
26 Bull, P., Ferreira, P. G., Patel, P. and Santos, M. G., “Late-time cosmology with 21 cm intensity mapping experiments”, Astrophys. J., 803, 21 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1405.1452].
27 Bunn, E. F. and Hogg, D. W., “The kinematic origin of the cosmological redshift”, Am. J. Phys., 77, 688–694 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0808.1081 [physics.pop-ph]].
28 Burud, I. et al., “An Optical Time Delay Estimate for the Double Gravitational Lens System B1600+434”, Astrophys. J., 544, 117–122 (2000). [External LinkDOI], [External LinkADS].
29 Burud, I. et al., “An optical time-delay for the lensed BAL quasar HE 2149–2745”, Astron. Astrophys., 383, 71–81 (2002). [External LinkDOI], [External LinkADS].
30 Burud, I. et al., “Time delay and lens redshift for the doubly imaged BAL quasar SBS 1520+530”, Astron. Astrophys., 391, 481 (2002). [External LinkDOI], [External LinkADS].
31 Busca, N. G. et al., “Baryon acoustic oscillations in the Lyα forest of BOSS quasars”, Astron. Astrophys., 552, A96 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1211.2616 [astro-ph.CO]].
32 Caldwell, R. R., Kamionkowski, M. and Weinberg, N. N., “Phantom Energy: Dark Energy with w < 1 Causes a Cosmic Doomsday”, Phys. Rev. Lett., 91, 071301 (2003). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0302506].
33 Carlstrom, J. E., Holder, G. P. and Reese, E. D., “Cosmology with the Sunyaev–Zel’dovich Effect”, Annu. Rev. Astron. Astrophys., 40, 643–680 (2002). [External LinkDOI], [External LinkADS].
34 Carroll, S. M., “The Cosmological Constant”, Living Rev. Relativity, 4, lrr-2001-1 (2001). [External LinkDOI]. URL (accessed 8 May 2007):
http://www.livingreviews.org/lrr-2001-1.
35 Chen, G., Gott III, J. R. and Ratra, B., “Non-Gaussian Error Distribution of Hubble Constant Measurements”, Publ. Astron. Soc. Pac., 115, 1269–1279 (2003). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0308099].
36 Chernoff, D. F. and Finn, L. S., “Gravitational radiation, inspiraling binaries, and cosmology”, Astrophys. J., 411, L5–L8 (1993). [External LinkDOI], [External LinkarXiv:gr-qc/9304020].
37 Cheung, C. C. et al., “Fermi Large Area Telescope Detection of Gravitational Lens Delayed γ-Ray Flares from Blazar B0218+357”, Astrophys. J. Lett., 782, L14 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1401.0548].
38 Cohn, J. D., Kochanek, C. S., McLeod, B. A. and Keeton, C. R., “Constraints on Galaxy Density Profiles from Strong Gravitational Lensing: The Case of B1933+503”, Astrophys. J., 554, 1216–1226 (2001). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0008390].
39 Collett, T. E., Auger, M. W., Belokurov, V., Marshall, P. J. and Hall, A. C., “Constraining the dark energy equation of state with double-source plane strong lenses”, Mon. Not. R. Astron. Soc., 424, 2864 (2012). [External LinkDOI].
40 Conley, A. et al., “Supernova Constraints and Systematic Uncertainties from the First Three Years of the Supernova Legacy Survey”, Astrophys. J. Suppl. Ser., 192, 1 (2011). [External LinkDOI], [External LinkADS], [External LinkarXiv:1104.1443].
41 Courbin, F. et al., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. IX. Time delays, lens dynamics and baryonic fraction in HE 0435-1223”, Astron. Astrophys., 536, A53 (2011). [External LinkDOI], [External LinkADS], [External LinkarXiv:1009.1473].
42 Croton, D. J., “Damn You, Little h! (Or, Real-World Applications of the Hubble Constant Using Observed and Simulated Data)”, Publ. Astron. Soc. Australia, 30, e052 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1308.4150 [astro-ph.CO]].
43 Curtis, H. D., “Modern Theories of the Spiral Nebulae”, J. R. Astron. Soc. Can., 14, 317–327 (1920). [External LinkADS].
44 Dai, X., Chartas, G., Agol, E., Bautz, M. W. and Garmire, G. P., “Chandra Observations of QSO 2237+0305”, Astrophys. J., 589, 100–110 (2003). [External LinkDOI], [External LinkADS].
45 Dalal, N., Holz, D. E., Hughes, S. A. and Jain, B., “Short GRB and binary black hole standard sirens as a probe of dark energy”, Phys. Rev. D, 74, 063006 (2006). [External LinkDOI], [External Linkastro-ph/0601275].
46 Dawson, K. S. et al. (Supernova Cosmology Project), “An Intensive Hubble Space Telescope Survey for z > 1 Type Ia Supernovae by Targeting Galaxy Clusters”, Astron. J., 138, 1271–1283 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0908.3928].
47 de Bernardis, P. et al., “A flat Universe from high-resolution maps of the cosmic microwave background radiation”, Nature, 404, 955–959 (2000). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0004404].
48 Delubac, T. et al., “Baryon acoustic oscillations in the Lyα forest of BOSS DR11 quasars”, Astron. Astrophys., 574, A59 (2015). [External LinkDOI], [External LinkADS], [External LinkarXiv:1404.1801].
49 Djorgovski, S. and Davis, M., “Fundamental properties of elliptical galaxies”, Astrophys. J., 313, 59–68 (1987). [External LinkDOI], [External LinkADS].
50 Dobler, G., Fassnacht, C., Treu, T., Marshall, P. J., Liao, K., Hojjati, A., Linder, E. and Rumbaugh, N., “Strong Lens Time Delay Challenge. I. Experimental Design”, Astrophys. J., 799, 168 (2015). [External LinkDOI], [External LinkADS], [External LinkarXiv:1310.4830].
51 Dobler, G. and Keeton, C. R., “Microlensing of Lensed Supernovae”, Astrophys. J., 653, 1391 (2006). [External LinkDOI].
52 Dominguez, A. and Prada, F., “Measurement of the Expansion Rate of the Universe from γ-ray Attenuation”, Astrophys. J., 771, L34 (2013). [External LinkDOI].
53 Dressler, A., Lynden-Bell, D., Burstein, D., Davies, R. L., Faber, S. M., Terlevich, R. and Wegner, G., “Spectroscopy and photometry of elliptical galaxies. I – A new distance estimator”, Astrophys. J., 313, 42–58 (1987). [External LinkDOI], [External LinkADS].
54 Efstathiou, G., “H0 revisited”, Mon. Not. R. Astron. Soc., 440, 1138–1152 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1311.3461 [astro-ph.CO]].
55 Eisenstein, D. J., Hu, W. and Tegmark, M., “Cosmic Complementarity: H0 and Ωm from combining Cosmic Microwave Background experiments and redshift surveys”, Astrophys. J., 504, L57–L60 (1998). [External LinkDOI], [External LinkADS], [External Linkastro-ph/9805239].
56 Eisenstein, D. J. et al., “Detection of the Baryon Acoustic Peak in the Large-Scale Correlation Function of SDSS Luminous Red Galaxies”, Astrophys. J., 633, 560–574 (2005). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0501171].
57 Eulaers, E. et al., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. XII. Time delays of the doubly lensed quasars SDSS J1206+4332 and HS 2209+1914”, Astron. Astrophys., 553, A121 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1304.4474].
58 Faber, S. M. and Jackson, R. E., “Velocity dispersions and mass-to-light ratios for elliptical galaxies”, Astrophys. J., 204, 668–683 (1976). [External LinkDOI], [External LinkADS].
59 Fassnacht, C. D., Gal, R. R., Lubin, L. M., McKean, J. P., Squires, G. K. and Readhead, A. C. S., “Mass along the Line of Sight to the Gravitational Lens B1608+656: Galaxy Groups and Implications for H0”, Astrophys. J., 642, 30–38 (2006). [External LinkDOI], [External LinkADS].
60 Fassnacht, C. D. and Lubin, L. M., “The Gravitational Lens-Galaxy Group Connection. I. Discovery of a Group Coincident with CLASS B0712+472”, Astron. J., 123, 627–636 (2002). [External LinkDOI], [External LinkADS].
61 Fassnacht, C. D., Xanthopoulos, E., Koopmans, L. V. E. and Rusin, D., “A Determination of H0 with the CLASS Gravitational Lens B1608+656. III. A Significant Improvement in the Precision of the Time Delay Measurements”, Astrophys. J., 581, 823–835 (2002). [External LinkDOI], [External LinkADS].
62 Feast, M. W., “The Distance to the Large Magellanic Cloud; A Critical Review”, in Chu, Y.-H., Suntzeff, N. B., Hesser, J. E. and Bohlender, D. A., eds., New Views of the Magellanic Clouds, Proceedings of the 190th Symposium of the IAU, held in Victoria, BC, Canada, July 12 – 17, 1998, 190, pp. 542–548, (Astronomical Society of the Pacific, San Francisco, 1999). [External LinkADS].
63 Feast, M. W. and Catchpole, R. M., “The Cepheid period-luminosity zero-point from HIPPARCOS trigonometrical parallaxes”, Mon. Not. R. Astron. Soc., 286, L1–L5 (1997). [External LinkDOI], [External LinkADS].
64 Fohlmeister, J., Kochanek, C. S., Falco, E. E., Wambsganss, J., Oguri, M. and Dai, X., “A Two-year Time Delay for the Lensed Quasar SDSS J1029+2623”, Astrophys. J., 764, 186 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1207.5776].
65 Fohlmeister, J. et al., “A Time Delay for the Largest Gravitationally Lensed Quasar: SDSSJ1004+4112”, arXiv, e-print, (2006). [External LinkarXiv:astro-ph/0607513].
66 Fouqué, P. and Gieren, W. P., “An improved calibration of Cepheid visual and infrared surface brightness relations from accurate angular diameter measurements of cool giants and supergiants”, Astron. Astrophys., 320, 799–810 (1997). [External LinkADS].
67 Fouqué, P., Storm, J. and Gieren, W., “Calibration of the Distance Scale from Cepheids”, in Alloin, D. and Gieren, W., eds., Stellar Candles for the Extragalactic Distance Scale, Lecture Notes in Physics, 635, pp. 21–44, (Springer, Berlin; New York, 2003).
68 Freedman, W. L. and Madore, B. F., “The Hubble Constant”, Annu. Rev. Astron. Astrophys., 48, 673–710 (2010). [External LinkDOI], [External LinkADS], [External LinkarXiv:1004.1856].
69 Freedman, W. L., Madore, B. F., Scowcroft, V., Burns, C., Monson, A., Persson, S. E., Seibert, M. and Rigby, J., “Carnegie Hubble Program: A Mid-infrared Calibration of the Hubble Constant”, Astrophys. J., 758, 24 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1208.3281].
70 Freedman, W. L., Wilson, C. D. and Madore, B. F., “New Cepheid distances to nearby galaxies based on BVRI CCD photometry. II. The local group galaxy M33”, Astrophys. J., 372, 455–470 (1991). [External LinkDOI], [External LinkADS].
71 Freedman, W. L. et al. (HST Collaboration), “Final Results from the Hubble Space Telescope Key Project to Measure the Hubble Constant”, Astrophys. J., 553, 47–72 (2001). [External LinkDOI], [External LinkADS].
72 Friedman, A. A., “Über die Krümmung des Raumes”, Z. Phys., 10, 377–386 (1922). [External LinkDOI]. English translation in Cosmological Constants: Papers in Modern Cosmology, eds. Bernstein, J. and Feinberg, G., (Columbia University Press, New York, 1986).
73 Frieman, J. A. et al. (SDSS Collaboration), “The Sloan Digital Sky Survey-II Supernova Survey: Technical Summary”, Astron. J., 135, 338–347 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0708.2749].
74 Gavazzi, R., Treu, T., Koopmans, L. V. E., Bolton, A. S., Moustakas, L. A., Burles, S. and Marshall, P. J., “The Sloan Lens ACS Survey. VI. Discovery and Analysis of a Double Einstein Ring”, Astrophys. J., 677, 1046–1059 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0801.1555].
75 Gieren, W. P., Fouqué, P. and Gómez, M., “Cepheid Period-Radius and Period-Luminosity Relations and the Distance to the Large Magellanic Cloud”, Astrophys. J., 496, 17–30 (1998). [External LinkDOI], [External LinkADS].
76 Gorenstein, M. V., Shapiro, I. I. and Falco, E. E., “Degeneracies in parameter estimation in models of gravitational lens systems”, Astrophys. J., 327, 693–711 (1988). [External LinkDOI], [External LinkADS].
77 Gott III, J. R., Vogeley, M. S., Podariu, S. and Ratra, B., “Median Statistics, H0 and the Accelerating Universe”, Astrophys. J., 549, 1–17 (2001). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0006103].
78 Greene, Z. S. et al., “Improving the Precision of Time-delay Cosmography with Observations of Galaxies along the Line of Sight”, Astrophys. J., 768, 39 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1303.3588].
79 Greenhill, L. J., Jiang, D. R., Moran, J. M., Reid, M. J., Lo, K. Y. and Claussen, M. J., “Detection of a Subparsec Diameter Disk in the Nucleus of NGC 4258”, Astrophys. J., 440, 619–627 (1995). [External LinkDOI], [External LinkADS].
80 Greenhill, L. J., Kondratko, P. T., Moran, J. M. and Tilak, A., “Discovery of Candidate H2O Disk Masers in Active Galactic Nuclei and Estimations Of Centripetal Accelerations”, Astrophys. J., 707, 787–799 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0911.0382].
81 Groenewegen, M. A. T., Romaniello, M., Primas, F. and Mottini, M., “The metallicity dependence of the Cepheid PL-relation”, Astron. Astrophys., 420, 655–663 (2004). [External LinkDOI], [External LinkADS].
82 Hamuy, M., Phillips, M. M., Suntzeff, N. B., Schommer, R. A., Maza, J., Smith, R. C., Lira, P. and Aviles, R., “The Morphology of Type Ia Supernovae Light Curves”, Astron. J., 112, 2438–2447 (1996). [External LinkDOI], [External LinkADS], [External Linkastro-ph/9609059].
83 Hanany, S. et al., “MAXIMA-1: A Measurement of the Cosmic Microwave Background Anisotropy on Angular Scales of 10–5”, Astrophys. J. Lett., 545, L5–L9 (2000). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0005123].
84 Herrnstein, J. R. et al., “A geometric distance to the galaxy NGC4258 from orbital motions in a nuclear gas disk”, Nature, 400, 539–541 (1999). [External LinkDOI], [External LinkADS].
85 Heymans, C. et al., “CFHTLenS: the Canada-France-Hawaii Telescope Lensing Survey”, Mon. Not. R. Astron. Soc., 427, 146–166 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1210.0032].
86 Hjorth, J. et al., “The Time Delay of the Quadruple Quasar RX J0911.4+0551”, Astrophys. J., 572, L11–L14 (2002). [External LinkDOI], [External LinkADS].
87 Hogg, D. W., “Distance measures in cosmology”, arXiv, e-print, (1999). [External LinkarXiv:astro-ph/9905116].
88 Hojjati, A., Kim, A. G. and Linder, E. V., “Robust strong lensing time delay estimation”, Phys. Rev. D, 87, 3512 (2013). [External LinkDOI].
89 Holtzman, J. A. et al., “The Sloan Digital Sky Survey-II: Photometry and Supernova IA Light Curves from the 2005 Data”, Astron. J., 136, 2306–2320 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0908.4277].
90 Holz, D. E. and Hughes, S. A., “Using Gravitational-Wave Standard Sirens”, Astrophys. J., 629, 15–22 (2005). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0504616].
91 Hu, W., “Dark Energy Probes in Light of the CMB”, in Wolff, S. C. and Lauer, T. R., eds., Observing Dark Energy, Proceedings of a meeting held in Tucson, AZ, USA, March 18 – 20, 2004, ASP Conference Series, 339, pp. 215–234, (Astronomical Society of the Pacific, San Francisco, 2005).
92 Hu, W. and Dodelson, S., “Cosmic Microwave Background Anisotropies”, Annu. Rev. Astron. Astrophys., 40, 171–216 (2002). [External LinkDOI], [External LinkADS].
93 Hubble, E. P., “NGC 6822, a remote stellar system”, Astrophys. J., 62, 409–433 (1925). [External LinkDOI], [External LinkADS].
94 Hubble, E. P., “A spiral nebula as a stellar system: Messier 33”, Astrophys. J., 63, 236–274 (1926). [External LinkDOI], [External LinkADS].
95 Hubble, E. P., “A Relation between Distance and Radial Velocity among Extra-Galactic Nebulae”, Proc. Natl. Acad. Sci. USA, 15, 168–173 (1929). [External LinkDOI].
96 Hubble, E. P., “A spiral nebula as a stellar system, Messier 31”, Astrophys. J., 69, 103–158 (1929). [External LinkDOI], [External LinkADS].
97 Humason, M. L., Mayall, N. U. and Sandage, A. R., “Redshifts and magnitudes of extragalactic nebulae”, Astron. J., 61, 97–162 (1956). [External LinkDOI], [External LinkADS].
98 Humphreys, E. M. L., Argon, A. L., Greenhill, L. J., Moran, J. M. and Reid, M. J., “Recent Progress on a New Distance to NGC 4258”, in Romney, J. D. and Reid, M. J., eds., Future Directions in High Resolution Astronomy: The 10th Anniversary of the VLBA, Proceedings of a meeting held in Socorro, NM, USA, June 8 – 12, 2003, ASP Conference Series, 340, pp. 466–470, (Astronomical Society of the Pacific, San Francisco, 2005).
99 Humphreys, E. M. L., Reid, M. J., Greenhill, L. J., Moran, J. M. and Argon, A. L., “Toward a New Geometric Distance to the Active Galaxy NGC 4258. II. Centripetal Accelerations and Investigation of Spiral Structure”, Astrophys. J., 672, 800–816 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0709.0925].
100 Humphreys, E. M. L., Reid, M. J., Moran, J. M., Greenhill, L. J. and Argon, A. L., “Toward a New Geometric Distance to the Active Galaxy NGC 4258. III. Final Results and the Hubble Constant”, Astrophys. J., 775, 13 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1307.6031].
101 Ivezić, Ž. et al. (LSST Collaboration), “LSST: from Science Drivers to Reference Design and Anticipated Data Products”, arXiv, e-print, (2008). [External LinkADS], [External LinkarXiv:0805.2366].
102 Jackson, N., “The Hubble Constant”, Living Rev. Relativity, 10, lrr-2007-4 (2007). [External LinkDOI]. URL (accessed 6 March 2014):
http://www.livingreviews.org/lrr-2007-4.
103 Jakobsson, P., Hjorth, J., Burud, I., Letawe, G., Lidman, C. and Courbin, F., “An optical time delay for the double gravitational lens system FBQ 0951+2635”, Astron. Astrophys., 431, 103–109 (2005). [External LinkDOI], [External LinkADS].
104 Jones, M. E. et al., “H0 from an orientation-unbiased sample of Sunyaev–Zel’dovich and X-ray clusters”, Mon. Not. R. Astron. Soc., 357, 518–526 (2005). [External LinkDOI], [External LinkADS].
105 Kaiser, N., “Astronomical redshifts and the expansion of space”, Mon. Not. R. Astron. Soc., 438, 2456–2465 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1312.1190 [astro-ph.CO]].
106 Keeton, C. R. and Zabludoff, A. I., “The Importance of Lens Galaxy Environments”, Astrophys. J., 612, 660–678 (2004). [External LinkDOI], [External LinkADS].
107 Kennicutt Jr, R. C., Bresolin, F. and Garnett, D. R., “The Composition Gradient in M101 Revisited. II. Electron Temperatures and Implications for the Nebular Abundance Scale”, Astrophys. J., 591, 801–820 (2003). [External LinkDOI], [External LinkADS].
108 Kervella, P., Nardetto, N., Bersier, D., Mourard, D. and Coudé du Foresto, V., “Cepheid distances from infrared long-baseline interferometry. I. VINCI/VLTI observations of seven Galactic Cepheids”, Astron. Astrophys., 416, 941–953 (2004). [External LinkDOI], [External LinkADS].
109 Kessler, R. et al., “First-Year Sloan Digital Sky Survey-II Supernova Results: Hubble Diagram and Cosmological Parameters”, Astrophys. J. Suppl. Ser., 185, 32–84 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0908.4274].
110 Kilbinger, M. et al., “CFHTLenS: combined probe cosmological model comparison using 2D weak gravitational lensing”, Mon. Not. R. Astron. Soc., 430, 2200–2220 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1212.3338].
111 Kochanek, C. S., “Rebuilding the Cepheid Distance Scale. I. A Global Analysis of Cepheid Mean Magnitudes”, Astrophys. J., 491, 13–28 (1997). [External LinkDOI], [External LinkADS].
112 Kochanek, C. S., “What Do Gravitational Lens Time Delays Measure?”, Astrophys. J., 578, 25–32 (2002). [External LinkDOI], [External LinkADS].
113 Kochanek, C. S., “Part 2: Strong Gravitational Lensing”, in Meylan, G., Jetzer, P. and North, P., eds., Gravitational Lensing: Strong, Weak and Micro, Saas-Fee Advanced Courses, 33, pp. 91–268, (Springer, Berlin; New York, 2004). [External LinkADS].
114 Kochanek, C. S., “Quantitative interpretation of quasar microlensing light curves”, Astrophys. J., 605, 58 (2004). [External LinkDOI].
115 Kochanek, C. S., Keeton, C. R. and McLeod, B. A., “The Importance of Einstein Rings”, Astrophys. J., 547, 50–59 (2001). [External LinkDOI], [External LinkADS].
116 Kochanek, C. S., Morgan, N. D., Falco, E. E., McLeod, B. A., Winn, J. N., Dembicky, J. and Ketzeback, B., “The Time Delays of Gravitational Lens HE 0435–1223: An Early-Type Galaxy with a Rising Rotation Curve”, Astrophys. J., 640, 47–61 (2006). [External LinkDOI], [External LinkADS].
117 Kochanek, C. S. and Schechter, P. L., “The Hubble Constant from Gravitational Lens Time Delays”, in Freedman, W. L., ed., Measuring and Modeling the Universe, Carnegie Observatories Centennial Symposium 2, Pasadena, CA, 17 – 22 September 2002, Carnegie Observatories Astrophysics Series, 2, pp. 117–137, (Cambridge University Press, Cambridge; New York, 2004). [External LinkADS].
118 Koopmans, L. V. E., de Bruyn, A. G., Xanthopoulos, E. and Fassnacht, C. D., “A time-delay determination from VLA light curves of the CLASS gravitational lens B1600+434”, Astron. Astrophys., 356, 391–402 (2000). [External LinkADS].
119 Koopmans, L. V. E., Treu, T., Bolton, A. S., Burles, S. and Moustakas, L. A., “The Sloan Lens ACS Survey. III. The Structure and Formation of Early-Type Galaxies and Their Evolution since z 1”, Astrophys. J., 640, 599–615 (2006). [External LinkDOI], [External LinkADS].
120 Koptelova, E., Oknyanskij, V. L., Artamonov, B. P. and Burkhonov, O., “Intrinsic quasar variability and time delay determination in the lensed quasar UM673”, Mon. Not. R. Astron. Soc., 401, 2805 (2010). [External LinkDOI].
121 Kundić, T. et al., “A Robust Determination of the Time Delay in 0957+561A, B and a Measurement of the Global Value of Hubble’s Constant”, Astrophys. J., 482, 75–82 (1997). [External LinkDOI], [External LinkADS].
122 Kuo, C. Y., Braatz, J. A., Reid, M. J., Lo, K. Y., Condon, J. J., Impellizzeri, C. M. V. and Henkel, C., “The Megamaser Cosmology Project. V. An Angular-diameter Distance to NGC 6264 at 140 Mpc”, Astrophys. J., 767, 155 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1207.7273].
123 Leavitt, H. S. and Pickering, E. C., Periods of 25 Variable Stars in the Small Magellanic Cloud., Harvard College Observatory Circular, 173, (Harvard College Observatory, Cambridge, 1912). [External LinkADS].
124 Lee, M. G., Kim, M., Sarajedini, A., Geisler, D. and Gieren, W., “Determination of the Distance to M33 Based on Single-Epoch I-Band Hubble Space Telescope Observations of Cepheids”, Astrophys. J., 565, 959–965 (2002). [External LinkDOI], [External LinkADS].
125 Lin, H. et al., “The SDSS co-add: cosmic shear measurement”, Astrophys. J., 761, 15 (2012). [External LinkDOI], [External LinkADS].
126 Linder, E. V., “Lensing time delays and cosmological complementarity”, Phys. Rev. D, 84, 123529 (2011). [External LinkDOI], [External LinkADS], [External LinkarXiv:1109.2592 [astro-ph.CO]].
127 Lovell, J. E. J., Jauncey, D. L., Reynolds, J. E., Wieringa, M. H., King, E. A., Tzioumis, A. K., McCulloch, P. M. and Edwards, P. G., “The Time Delay in the Gravitational Lens PKS 1830–211”, Astrophys. J. Lett., 508, L51–L54 (1998). [External LinkDOI], [External LinkADS].
128 Lynden-Bell, D., Burstein, D., Davies, R. L., Dressler, A. and Faber, S. M., “On best distance estimators and galaxy streaming”, in van den Bergh, S. and Pritchet, C. J., eds., The Extragalactic Distance Scale, Proceedings of the ASP 100th Anniversary Symposium, held in Victoria, BC, Canada, June 29 – July 1, 1988, ASP Conference Series, 4, pp. 307–316, (Astronomical Society of the Pacific, San Francisco, 1988). [External LinkADS].
129 Macri, L. M., Stanek, K. Z., Bersier, D., Greenhill, L. J. and Reid, M. J., “A New Cepheid Distance to the Maser-Host Galaxy NGC 4258 and Its Implications for the Hubble Constant”, Astrophys. J., 652, 1133–1149 (2006). [External LinkDOI], [External LinkADS].
130 Marra, V., Amendola, L., Sawicki, I. and Valkenburg, W., “Cosmic Variance and the Measurement of the Local Hubble Parameter”, Phys. Rev. Lett., 110, 241305 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1303.3121 [astro-ph.CO]].
131 Mason, B. S., Myers, S. T. and Readhead, A. C. S., “A Measurement of H0 from the Sunyaev–Zeldovich Effect”, Astrophys. J. Lett., 555, L11–L15 (2001). [External LinkDOI], [External LinkADS].
132 Masters, K. L., Springob, C. M., Haynes, M. P. and Giovanelli, R., “SFI++ I: A New I-Band Tully-Fisher Template, the Cluster Peculiar Velocity Dispersion, and H0”, Astrophys. J., 653, 861–880 (2006). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0609249].
133 McDonald, P. et al., “The linear theory power spectrum from the Lyα forest in the sloan digital sky survey”, Astrophys. J., 635, 761–783 (2005). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0407377].
134 Mehta, K. T., Cuesta, A. J., Xu, X., Eisenstein, D. J. and Padmanabhan, N., “A 2 per cent distance to z = 0.35 by reconstructing baryon acoustic oscillations – III. Cosmological measurements and interpretation”, Mon. Not. R. Astron. Soc., 427, 2168–2179 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1202.0092 [astro-ph.CO]].
135 Miknaitis, G. et al., “The ESSENCE Supernova Survey: Survey Optimization, Observations, and Supernova Photometry”, Astrophys. J., 666, 674–693 (2007). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0701043].
136 Miyoshi, M., Moran, J., Herrnstein, J., Greenhill, L., Nakai, N., Diamond, P. and Inoue, M., “Evidence for a Black Hole from High Rotation Velocities in a Sub-Parsec Region of NGC4258”, Nature, 373, 127–129 (1995). [External LinkDOI], [External LinkADS].
137 Momcheva, I., Williams, K. A., Keeton, C. R. and Zabludoff, A. I., “A Spectroscopic Study of the Environments of Gravitational Lens Galaxies”, Astrophys. J., 641, 169–189 (2006). [External LinkDOI], [External LinkADS].
138 Morgan, N. D., Kochanek, C. S., Falco, E. E. and Dai, X., “Time-Delays and Mass Models for the Quadruple Lens RXJ1131-1231”, 2007 AAS/AAPT Joint Meeting held in Seattle, WA, USA, January 5 – 10, 2007, conference paper, (2006). [External LinkADS]. AAS Poster 021.07.
139 Navarro, J. F., Frenk, C. S. and White, S. D. M., “The Structure of Cold Dark Matter Halos”, Astrophys. J., 462, 563–575 (1996). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/9508025].
140 Ofek, E. O. and Maoz, D., “Time-Delay Measurement of the Lensed Quasar HE 1104–1805”, Astrophys. J., 594, 101–106 (2003). [External LinkDOI], [External LinkADS].
141 Oguri, M., “Gravitational Lens Time Delays: A Statistical Assessment of Lens Model Dependences and Implications for the Global Hubble Constant”, Astrophys. J., 660, 1–15 (2007). [External LinkDOI], [External LinkADS].
142 Oguri, M. and Kawano, Y., “Gravitational lens time delays for distant supernovae: breaking the degeneracy between radial mass profiles and the Hubble constant”, Mon. Not. R. Astron. Soc., 338, L25–L29 (2003). [External LinkDOI], [External LinkADS].
143 Oguri, M., Suto, Y. and Turner, E. L., “Gravitational Lensing Magnification and Time Delay Statistics for Distant Supernovae”, Astrophys. J., 583, 584–593 (2003). [External LinkDOI], [External LinkADS].
144 Olling, R. P., “Accurate Extra-Galactic Distances and Dark Energy: Anchoring the Distance Scale with Rotational Parallaxes”, arXiv, e-print, (2006). [External LinkarXiv:astro-ph/0607607].
145 Olling, R. P. and Peterson, D. M., “Galaxy Distances via Rotational Parallaxes”, arXiv, e-print, (2000). [External LinkarXiv:astro-ph/0005484].
146 Oscoz, A., Serra-Ricart, M., Mediavilla, E. and Muñoz, J. A., “Long-term Monitoring, Time Delay, and Microlensing in the Gravitational Lens System Q0142-100”, Astrophys. J., 779, 144 (2013). [External LinkDOI].
147 Paczyński, B., “Detached Eclipsing Binaries as Primary Distance and Age Indicators”, in Livio, M., Donahue, M. and Panagia, N., eds., The Extragalactic Distance Scale, Proceedings of the ST ScI May Symposium, held in Baltimore, MD, May 7 – 10, 1996, Space Telescope Science Institute Symposium Series, pp. 273–280, (Cambridge University Press, Cambridge; New York, 1997).
148 Padmanabhan, N., Xu, X., Eisenstein, D. J., Scalzo, R., Cuesta, A. J., Mehta, K. T. and Kazin, E., “A 2 per cent distance to z = 0.35 by reconstructing baryon acoustic oscillations – I. Methods and application to the Sloan Digital Sky Survey”, Mon. Not. R. Astron. Soc., 427, 2132–2145 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1202.0090].
149 Panagia, N., Gilmozzi, R., Macchetto, F., Adorf, H.-M. and Kirshner, R. P., “Properties of the SN 1987A circumstellar ring and the distance to the Large Magellanic Cloud”, Astrophys. J. Lett., 380, L23–L26 (1991). [External LinkDOI], [External LinkADS].
150 Paraficz, D. and Hjorth, J., “The Hubble Constant Inferred from 18 Time-delay Lenses”, Astrophys. J., 712, 1378 (2010). [External LinkDOI].
151 Patnaik, A. R. and Narasimha, D., “Determination of time delay from the gravitational lens B1422+231”, Mon. Not. R. Astron. Soc., 326, 1403–1411 (2001). [External LinkDOI], [External LinkADS].
152 Paturel, G. and Teerikorpi, P., “The extragalactic Cepheid distance bias: Numerical simulations”, Astron. Astrophys., 413, L31–L34 (2004). [External LinkDOI].
153 Paturel, G. and Teerikorpi, P., “The extragalactic Cepheid bias: significant influence on the cosmic distance scale”, Astron. Astrophys., 443, 883–889 (2005). [External LinkDOI].
154 Paturel, G. and Teerikorpi, P., “The extragalactic Cepheid bias: a new test using the period-luminosity-color relation”, Astron. Astrophys., 452, 423–430 (2006). [External LinkDOI].
155 Peacock, J. A., Cosmological Physics, (Cambridge University Press, Cambridge; New York, 1999). [External LinkADS], [External LinkGoogle Books].
156 Pelt, J., Kayser, R., Refsdal, S. and Schramm, T., “The light curve and the time delay of QSO 0957+561”, Astron. Astrophys., 305, 97 (1996). [External LinkADS], [External LinkarXiv:astro-ph/9501036].
157 Perlmutter, S. et al., “Measurements of the Cosmological Parameters Omega and Lambda from the First Seven Supernovae at z 0.35”, Astrophys. J., 483, 565–581 (1997). [External LinkDOI], [External LinkADS].
158 Perlmutter, S. et al. (Supernova Cosmology Project), “Measurements of Ω and Λ from 42 High-Redshift Supernovae”, in Paul, J., Montmerle, T. and Aubourg, E., eds., Abstracts of the 19th Texas Symposium on Relativistic Astrophysics and Cosmology, Paris, France, December 14 – 18, 1998, p. 146, (Aubourg (CEA Saclay), Paris, 1998).
159 Perryman, M. A. C. et al., “The Hyades: distance, structure, dynamics, and age”, Astron. Astrophys., 331, 81–120 (1998). [External LinkADS], [External Linkastro-ph/9707253].
160 Persson, S. E., Madore, B. F., Krzemiński, W., Freedman, W. L., Roth, M. and Murphy, D. C., “New Cepheid Period-Luminosity Relations for the Large Magellanic Cloud: 92 Near-Infrared Light Curves”, Astron. J., 128, 2239–2264 (2004). [External LinkDOI], [External LinkADS].
161 Peterson, D. and Shao, M., “The Scientific Basis for the Space Interferometry Mission”, in Battrick, B., ed., Hipparcos Venice ’97 Symposium: Presenting The Hipparcos and Tycho Catalogues and first astrophysical results of the Hipparcos astrometry mission, Proceedings of the ESA Symposium, Venice, Italy, May 13 – 16, 1997, SP-402, pp. 749–753, (ESA Publications Division, Noordwijk, 1997). [External LinkADS]. Online version (accessed 10 September 2007):
External Linkhttp://www.rssd.esa.int/?project=HIPPARCOS&page=venice97.
162 Phillips, M. M., “The absolute magnitudes of Type Ia supernovae”, Astrophys. J. Lett., 413, L105–L108 (1993). [External LinkDOI], [External LinkADS].
163 Pskovskii, Y. P., “The Photometric Properties of Supernovae”, Sov. Astron., 11, 63–69 (1967). [External LinkADS].
164 Rathna Kumar, S. et al., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. XIV. Time delay of the doubly lensed quasar SDSS J1001+5027”, Astron. Astrophys., 557, A44 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1306.5105].
165 Reese, E. D., Carlstrom, J. E., Joy, M., Mohr, J. J., Grego, L. and Holzapfel, W. L., “Determining the Cosmic Distance Scale from Interferometric Measurements of the Sunyaev–Zeldovich Effect”, Astrophys. J., 581, 53–85 (2002). [External LinkDOI], [External LinkADS].
166 Refsdal, S., “On the possibility of determining Hubble’s parameter and the masses of galaxies from the gravitational lens effect”, Mon. Not. R. Astron. Soc., 128, 307–310 (1964). [External LinkADS].
167 Reid, M. J., Braatz, J. A., Condon, J. J., Greenhill, L. J., Henkel, C. and Lo, K. Y., “The Megamaser Cosmology Project. I. Very Long Baseline Interferometric Observations of UGC 3789”, Astrophys. J., 695, 287–291 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0811.4345].
168 Reid, M. J., Braatz, J. A., Condon, J. J., Lo, K. Y., Kuo, C. Y., Impellizzeri, C. M. V. and Henkel, C., “The Megamaser Cosmology Project. IV. A Direct Measurement of the Hubble Constant from UGC 3789”, Astrophys. J., 767, 154 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1207.7292].
169 Riess, A. G. et al., “Observational Evidence from Supernovae for an Accelerating Universe and a Cosmological Constant”, Astron. J., 116, 1009–1038 (1998). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/9805201].
170 Riess, A. G. et al., “Cepheid Calibrations from the Hubble Space Telescope of the Luminosity of Two Recent Type Ia Supernovae and a Redetermination of the Hubble Constant”, Astrophys. J., 627, 579–607 (2005). [External LinkDOI], [External LinkADS].
171 Riess, A. G. et al., “New Hubble Space Telescope discoveries of Type Ia supernovae at z 1: Narrowing constraints on the early behaviour of dark energy”, Astrophys. J., 659, 98–121 (2007). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0611572].
172 Riess, A. G. et al., “Cepheid Calibrations of Modern Type Ia Supernovae: Implications for the Hubble Constant”, Astrophys. J. Suppl. Ser., 183, 109–141 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0905.0697].
173 Riess, A. G. et al., “A Redetermination of the Hubble Constant with the Hubble Space Telescope from a Differential Distance Ladder”, Astrophys. J., 699, 539–563 (2009). [External LinkDOI], [External LinkADS], [External LinkarXiv:0905.0695].
174 Riess, A. G. et al., “A 3% Solution: Determination of the Hubble Constant with the Hubble Space Telescope and Wide Field Camera 3”, Astrophys. J., 730, 119 (2011). [External LinkDOI], [External LinkADS], [External LinkarXiv:1103.2976].
175 Rodney, S. A. et al., “A Type Ia Supernova at Redshift 1.55 in Hubble Space Telescope Infrared Observations from CANDELS”, Astrophys. J., 746, 5 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1201.2470].
176 Rowan-Robinson, M., The Cosmological Distance Ladder: Distance and Time in the Universe, (W.H. Freeman, New York, 1985).
177 Saha, P., Coles, J., Macció, A. V. and Williams, L. L. R., “The Hubble Time Inferred from 10 Time Delay Lenses”, Astrophys. J. Lett., 650, L17–L20 (2006). [External LinkDOI], [External LinkADS].
178 Saha, P., Coles, J., Macció, A. V. and Williams, L. L. R., “The Hubble Time Inferred from 10 Time Delay Lenses”, Astrophys. J., 650, L17 (2006). [External LinkDOI].
179 Saha, P. and Williams, L. L. R., “Non-parametric reconstruction of the galaxy lens in PG 1115+080”, Mon. Not. R. Astron. Soc., 292, 148–156 (1997). [External LinkDOI], [External LinkADS].
180 Saha, P. and Williams, L. L. R., “Beware the Nonuniqueness of Einstein Rings”, Astron. J., 122, 585–590 (2001). [External LinkDOI], [External LinkADS].
181 Sakai, S., Ferrarese, L., Kennicutt Jr, R. C. and Saha, A., “The Effect of Metallicity on Cepheid-based Distances”, Astrophys. J., 608, 42–61 (2004). [External LinkDOI], [External LinkADS].
182 Sako, M. et al., “The Sloan Digital Sky Survey-II Supernova Survey: Search Algorithm and Follow-up Observations”, Astron. J., 135, 348 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0708.2750].
183 Salamon, M. H., Stecker, F. W. and de Jager, O. C., “A new method for determining the Hubble constant from sub-TeV gamma-ray observations”, Astrophys. J., 423, L1 (1994). [External LinkDOI].
184 Sánchez, E., Alonso, D., Sánchez, F. J., García-Bellido, J. and Sevilla, I., “Precise measurement of the radial baryon acoustic oscillation scales in galaxy redshift surveys”, Mon. Not. R. Astron. Soc., 434, 2008–2019 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1210.6446 [astro-ph.CO]].
185 Sandage, A., “Current Problems in the Extragalactic Distance Scale”, Astrophys. J., 127, 513–526 (1958). [External LinkDOI], [External LinkADS].
186 Sandage, A., “Cepheids as distance indicators when used near their detection limit”, Publ. Astron. Soc. Pac., 100, 935–948 (1988). [External LinkDOI], [External LinkADS].
187 Sandage, A., Tammann, G. A., Saha, A., Reindl, B., Macchetto, F. D. and Panagia, N., “The Hubble Constant: A Summary of the Hubble Space Telescope Program for the Luminosity Calibration of Type Ia Supernovae by Means of Cepheids”, Astrophys. J., 653, 843–860 (2006). [External LinkDOI], [External LinkADS].
188 Schechter, P. L. et al., “The Quadruple Gravitational Lens PG 1115+080: Time Delays and Models”, Astrophys. J. Lett., 475, L85–L88 (1997). [External LinkDOI], [External LinkADS].
189 Schild, R. and Thomson, D. J., “The Q0957+561 Time Delay From Optical Data”, Astron. J., 113, 130–135 (1997). [External LinkDOI], [External LinkADS].
190 Schmidt, R. W., Allen, S. W. and Fabian, A. C., “An improved approach to measuring H0 using X-ray and SZ observations of galaxy clusters”, Mon. Not. R. Astron. Soc., 352, 1413–1420 (2004). [External LinkDOI], [External LinkADS].
191 Schneider, P., “Can one determine cosmological parameters from multi-plane strong lens systems?”, Astron. Astrophys., 568, L2 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1406.6152].
192 Schneider, P. and Sluse, D., “Mass-sheet degeneracy, power-law models and external convergence: Impact on the determination of the Hubble constant from gravitational lensing”, Astron. Astrophys., 559, A37 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1306.0901].
193 Schutz, B. F., “Determining the Hubble Constant from Gravitational Wave Observations”, Nature, 323, 310–311 (1986). [External LinkDOI].
194 Sereno, M. and Paraficz, D., “Hubble constant and dark energy inferred from free-form determined time delay distances”, Mon. Not. R. Astron. Soc., 437, 600 (2014). [External LinkDOI].
195 Shapley, H., “On the Existence of External Galaxies”, J. R. Astron. Soc. Can., 13, 438–446 (1919). [External LinkADS].
196 Silk, J. and White, S. D. M., “The determination of Q0 using X-ray and microwave observations of galaxy clusters”, Astrophys. J. Lett., 226, L103–L106 (1978). [External LinkDOI], [External LinkADS].
197 Slipher, V. M., “The Radial Velocity of the Andromeda Nebula”, Popular Astron., 22, 19–21 (1914). [External LinkADS].
198 Slipher, V. M., “Radial velocity observations of spiral nebulae”, Observatory, 40, 304–306 (1917). [External LinkADS].
199 Slosar, A. et al., “Measurement of baryon acoustic oscillations in the Lyman-α forest fluctuations in BOSS data release 9”, J. Cosmol. Astropart. Phys., 2013(04), 026 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1301.3459 [astro-ph.CO]].
200 Sparks, W. B., “A direct way to measure the distances of galaxies”, Astrophys. J., 433, 19–28 (1994). [External LinkDOI], [External LinkADS].
201 Spergel, D. N. et al. (WMAP Collaboration), “First-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Determination of Cosmological Parameters”, Astrophys. J. Suppl. Ser., 148, 175–194 (2003). [External LinkDOI], [External LinkADS].
202 Spergel, D. N. et al., “Three-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Implications for Cosmology”, Astrophys. J. Suppl. Ser., 170, 377–408 (2007). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0603449].
203 Sunyaev, R. A. and Zel’dovich, Y. B., “The Observations of Relic Radiation as a Test of the Nature of X-Ray Radiation from the Clusters of Galaxies”, Comments Astrophys. Space Phys., 4, 173 (1972).
204 Suyu, S., “Gravitational Lens Time Delays: Past, Present and Future”, The Return of de Sitter II, Max Planck Institute for Astrophysics, Garching, Germany, October 14 – 18, 2013, conference paper, (2013).
205 Suyu, S. H., Marshall, P. J., Auger, M. W., Hilbert, S., Blandford, R. D., Koopmans, L. V. E., Fassnacht, C. D. and Treu, T., “Dissecting the Gravitational lens B1608+656. II. Precision Measurements of the Hubble Constant, Spatial Curvature, and the Dark Energy Equation of State”, Astrophys. J., 711, 201–221 (2010). [External LinkDOI], [External LinkADS], [External LinkarXiv:0910.2773].
206 Suyu, S. H. et al., “Two Accurate Time-delay Distances from Strong Lensing: Implications for Cosmology”, Astrophys. J., 766, 70 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1208.6010].
207 Suyu, S. H. et al., “Cosmology from gravitational lens time delays and Planck data”, Astrophys. J., 788, L35 (2014). [External LinkDOI], [External LinkADS], [External LinkarXiv:1306.4732].
208 Suzuki, N. et al. (Supernova Cosmology Project), “The Hubble Space Telescope Cluster Supernova Survey. V. Improving the Dark-energy Constraints above z > 1 and Building an Early-type-hosted Supernova Sample”, Astrophys. J., 746, 85 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1105.3470].
209 Tammann, G. A., “Supernova statistics and related problems”, in Rees, M. J. and Stoneham, R. J., eds., Supernovae: A Survey of Current Research, Proceedings of the NATO Advanced Study Institute, held at Cambridge, UK, June 29 – July 10, 1981, NATO Science Series C, 90, pp. 371–403, (Kluwer, Dordrecht; Boston, 1982).
210 Tammann, G. A. and Reindl, B., “Karl Schwarzschild Lecture: The Ups and Downs of the Hubble Constant”, in Röser, S., ed., The Many Facets of the Universe – Revelations by New Instruments, Herbsttagung 2005 / 79th Annual Scientific Meeting of the Astronomische Gesellschaft, Cologne, Germany, September 26 – October 1, 2005, Reviews in Modern Astronomy, 19, pp. 1–30, (Wiley-VCH, Weinheim, 2006). [External LinkADS], [External Linkastro-ph/0512584].
211 Tammann, G. A., Sandage, A. and Reindl, B., “New Period-Luminosity and Period-Color relations of classical Cepheids: I. Cepheids in the Galaxy”, Astron. Astrophys., 404, 423–448 (2003). [External LinkDOI], [External LinkADS].
212 Tammann, G. A., Sandage, A. and Reindl, B., “The expansion field: the value of H0”, Astron. Astrophys. Rev., 15, 289–331 (2008). [External LinkDOI], [External LinkADS].
213 Teerikorpi, P., “Observational Selection Bias Affecting the Determination of the Extragalactic Distance Scale”, Annu. Rev. Astron. Astrophys., 35, 101–136 (1997). [External LinkDOI].
214 Teerikorpi, P. and Paturel, G., “Evidence for the extragalactic Cepheid distance bias from the kinematical distance scale”, Astron. Astrophys., 381, L37–L40 (2002). [External LinkDOI].
215 Tegmark, M. et al. (SDSS Collaboration), “The Three-Dimensional Power Spectrum of Galaxies from the Sloan Digital Sky Survey”, Astrophys. J., 606, 702–740 (2004). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0310725].
216 Tegmark, M. et al. (SDSS Collaboration), “Cosmological constraints from the SDSS luminous red galaxies”, Phys. Rev. D, 74, 123507 (2006). [External LinkDOI], [External LinkADS].
217 Tewes, M., Courbin, F. and Meylan, G., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. XI. Techniques for time delay measurement in presence of microlensing”, Astron. Astrophys., 553, A120 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1208.5598].
218 Thim, F., Tammann, G. A., Saha, A., Dolphin, A., Sandage, A., Tolstoy, E. and Labhardt, L., “The Cepheid Distance to NGC 5236 (M83) with the ESO Very Large Telescope”, Astrophys. J., 590, 256 (2003). [External LinkDOI].
219 Tonry, J. and Schneider, D. P., “A new technique for measuring extragalactic distances”, Astron. J., 96, 807–815 (1988). [External LinkDOI], [External LinkADS].
220 Treu, T. and Koopmans, L. V. E., “The Internal Structure and Formation of Early-Type Galaxies: The Gravitational Lens System MG 2016+112 at z = 1.004”, Astrophys. J., 575, 87–94 (2002). [External LinkDOI], [External LinkADS].
221 Treu, T. and Koopmans, L. V. E., “The internal structure of the lens PG1115+080: breaking degeneracies in the value of the Hubble constant”, Mon. Not. R. Astron. Soc., 337, L6–L10 (2002). [External LinkDOI], [External LinkADS], [External Linkastro-ph/0210002].
222 Treu, T. and Koopmans, L. V. E., “Massive Dark Matter Halos and Evolution of Early-Type Galaxies to z 1”, Astrophys. J., 611, 739–760 (2004). [External LinkDOI], [External LinkADS].
223 Trimble, V., “H0: The Incredible Shrinking Constant, 1925–1975”, Publ. Astron. Soc. Pac., 108, 1073–1082 (1996). [External LinkDOI], [External LinkADS].
224 Tully, R. B. and Fisher, J. R., “A new method of determining distances to galaxies”, Astron. Astrophys., 54, 661–673 (1977). [External LinkADS].
225 Turon, C., Luri, X. and Masana, E., “Building the cosmic distance scale: from Hipparcos to Gaia”, Astrophys. Space. Sci., 341, 15–29 (2012). [External LinkDOI], [External LinkADS], [External LinkarXiv:1202.3645 [astro-ph.IM]].
226 Tytler, D. et al., “Cosmological Parameters σ8, the Baryon Density Ωb, the Vacuum Energy Density ΩΛ, the Hubble Constant and the UV Background Intensity from a Calibrated Measurement of H I Lyα Absorption at z = 1.9”, Astrophys. J., 617, 1–28 (2004). [External LinkDOI], [External LinkADS].
227 Udalski, A., Soszynski, I., Szymański, M., Kubiak, M., Pietrzynski, G., Wozniak, P. and Zebrun, K., “The Optical Gravitational Lensing Experiment. Cepheids in the Magellanic Clouds. IV. Catalog of Cepheids from the Large Magellanic Cloud”, Acta Astron., 49, 223–317 (1999). [External LinkADS].
228 Udomprasert, P. S., Mason, B. S., Readhead, A. C. S. and Pearson, T. J., “An Unbiased Measurement of H0 through Cosmic Background Imager Observations of the Sunyaev–Zel’dovich Effect in Nearby Galaxy Clusters”, Astrophys. J., 615, 63–81 (2004). [External LinkDOI], [External LinkADS].
229 Ullán, A., Goicoechea, L. J., Zheleznyak, A. P., Koptelova, E., Bruevich, V. V., Akhunov, T. and Burkhonov, O., “Time delay of SBS 0909+532”, Astron. Astrophys., 452, 25–35 (2006). [External LinkDOI], [External LinkADS].
230 Vuissoz, C. et al., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. V. The time delay in SDSS J1650+4251”, Astron. Astrophys., 464, 845–851 (2007). [External LinkDOI], [External LinkADS].
231 Vuissoz, C. et al., “COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. VII. Time delays and the Hubble constant from WFI J2033-4723”, Astron. Astrophys., 488, 481–490 (2008). [External LinkDOI], [External LinkADS], [External LinkarXiv:0803.4015].
232 Walsh, D., Carswell, R. F. and Weymann, R. J., “0957 + 561 A, B: twin quasistellar objects or gravitational lens?”, Nature, 279, 381–384 (1979). [External LinkDOI], [External LinkADS].
233 Wambsganss, J., “Gravitational Lensing in Astronomy”, Living Rev. Relativity, 1, lrr-1998-12 (1998). [External LinkDOI]. URL (accessed 25 June 2007):
http://www.livingreviews.org/lrr-1998-12.
234 Wang, X., Wang, L., Pain, R., Zhou, X. and Li, Z., “Determination of the Hubble Constant, the Intrinsic Scatter of Luminosities of Type Ia Supernovae, and Evidence for Nonstandard Dust in Other Galaxies”, Astrophys. J., 645, 488–505 (2006). [External LinkDOI], [External LinkADS].
235 Weinberg, D. H., Mortonson, M. J., Eisenstein, D. J., Hirata, C., Riess, A. G. and Rozo, E., “Observational probes of cosmic acceleration”, Phys. Rep., 530, 87–255 (2013). [External LinkDOI], [External LinkADS], [External LinkarXiv:1201.2434].
236 Wesselink, A. J., “Surface brightnesses in the U, B, V system with applications of MV and dimensions of stars”, Mon. Not. R. Astron. Soc., 144, 297–311 (1969). [External LinkADS].
237 Williams, L. L. R. and Saha, P., “Pixelated Lenses and H0 from Time-Delay Quasars”, Astron. J., 119, 439–450 (2000). [External LinkDOI], [External LinkADS].
238 Wood-Vasey, W. M. et al., “Observational Constraints on the Nature of Dark Energy: First Cosmological Results from the ESSENCE Supernova Survey”, Astrophys. J., 666, 694–715 (2007). [External LinkDOI], [External LinkADS], [External LinkarXiv:astro-ph/0701041].
239 Wucknitz, O., Biggs, A. D. and Browne, I. W. A., “Models for the lens and source of B0218+357: a LENSCLEAN approach to determine H0”, Mon. Not. R. Astron. Soc., 349, 14–30 (2004). [External LinkDOI], [External LinkADS].
240 York, D. G. et al., “The Sloan Digital Sky Survey: Technical Summary”, Astron. J., 120, 1579–1587 (2000). [External LinkDOI], [External LinkADS].
241 York, T., Jackson, N., Browne, I. W. A., Wucknitz, O. and Skelton, J. E., “The Hubble constant from the gravitational lens CLASS B0218+357 using the Advanced Camera for Surveys”, Mon. Not. R. Astron. Soc., 357, 124–134 (2005). [External LinkDOI], [External LinkADS].
242 Zaritsky, D., Kennicutt Jr, R. C. and Huchra, J. P., “H ii regions and the abundance properties of spiral galaxies”, Astrophys. J., 420, 87–109 (1994). [External LinkDOI], [External LinkADS].