Spectral Classification and Redshift Measurement for the SDSS-III Baryon   Oscillation Spectroscopic Survey

Adam S. Bolton (1); David J. Schlegel (2); Eric Aubourg (3,4); Stephen; Bailey (2); Vaishali Bhardwaj (5); Joel R. Brownstein (1); Scott Burles (6),; Yan-Mei Chen (7); Kyle Dawson (1); Daniel J. Eisenstein (8); James E. Gunn; (9); G. R. Knapp (9); Craig P. Loomis (9); Robert H. Lupton (9); Claudia; Maraston (10); Demitri Muna (11); Adam D. Myers (12); Matthew D. Olmstead; (1); Nikhil Padmanabhan (13); Isabelle Paris (14,15); Will J. Percival (10),; Patrick Petitjean (14); Constance M. Rockosi (16); Nicholas P. Ross (2),; Donald P. Schneider (17,18); Yiping Shu (1); Michael A. Strauss (9); Daniel; Thomas (10); Christy A. Tremonti (7); David A. Wake (19); Benjamin A. Weaver; (11); W. Michael Wood-Vasey (20) ((1) U. of Utah; (2) LBNL; (3) APC; Paris-Diderot; (4) CEA Saclay; (5) U. of Washington; (6) Cutler Group; LP,; (7) U. of Wisconsin; (8) Harvard-Smithsonian CfA; (9) Princeton; (10); Portsmouth; (11) NYU; (12) U. of Wyoming; (13) Yale Physics; (14) IAP Paris,; (15) U. de Chile; (16) UCO/Lick UCSC; (17) Penn State Astronomy; (18) Penn; State IGC; (19) Yale Astronomy; (20) U. of Pittsburgh)

arXiv:1207.7326·astro-ph.CO·June 5, 2015

Spectral Classification and Redshift Measurement for the SDSS-III Baryon Oscillation Spectroscopic Survey

Adam S. Bolton (1), David J. Schlegel (2), Eric Aubourg (3,4), Stephen, Bailey (2), Vaishali Bhardwaj (5), Joel R. Brownstein (1), Scott Burles (6),, Yan-Mei Chen (7), Kyle Dawson (1), Daniel J. Eisenstein (8), James E. Gunn, (9), G. R. Knapp (9), Craig P. Loomis (9)

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TL;DR

This paper details the automated spectral classification and redshift measurement pipeline for SDSS-III BOSS, achieving high accuracy in classifying galaxies and quasars from over 800,000 spectra, with improvements over previous versions.

Contribution

It introduces new algorithms and templates for spectral classification and redshift determination, enhancing accuracy and efficiency for large-scale cosmological surveys.

Findings

01

Achieved 98.7% classification success rate for CMASS galaxy sample

02

Confirmed 95.4% of CMASS targets as galaxies

03

Redshift errors are typically a few tens of km/s, with underestimation factors identified

Abstract

(abridged) We describe the automated spectral classification, redshift determination, and parameter measurement pipeline in use for the Baryon Oscillation Spectroscopic Survey (BOSS) of the Sloan Digital Sky Survey III (SDSS-III) as of Data Release 9, encompassing 831,000 moderate-resolution optical spectra. We give a review of the algorithms employed, and describe the changes to the pipeline that have been implemented for BOSS relative to previous SDSS-I/II versions, including new sets of stellar, galaxy, and quasar redshift templates. For the color-selected CMASS sample of massive galaxies at redshift 0.4 <~ z <~ 0.8 targeted by BOSS for the purposes of large-scale cosmological measurements, the pipeline achieves an automated classification success rate of 98.7% and confirms 95.4% of unique CMASS targets as galaxies (with the balance being mostly M stars). Based on visual inspections…

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