Non-parametric Reconstruction of the Hubble Expansion History with a Monotonicity Prior Hu Zhan 1 & Youhua Xu 1, 2 1 National Astronomical Observatories.

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Non-parametric Reconstruction of the Hubble Expansion History with a Monotonicity Prior Hu Zhan 1 & Youhua Xu 1, 2 1 National Astronomical Observatories of China 2 Nanjing University COSMO-15 Sept 7-11, 2015 Warsaw, Poland

H(z) is a direct probe of the cosmic expansion history as well as the dark energy equation of state. Need for model-independent constraints on intermediate quantities. Cosmological constant? w? w 0 & w a ? Quintessence? Phantom? Modified gravity? Relatively model-independent constraints on P(k,z), d(z), g(z), H(z), etc. greatly facilitate DE/MG model tests. Cross checks between methods. Appropriate prior to regularize the reconstruction.

BigBOSS/DESI Zhan et al Levi et al Examples of Reconstruction & Forecasts Zhao et al. 2012

Galaxy Ages Line-of-sight BAOs H 0 Cepheids, SNe, maser, strong lensing, CMB etc. with a model. Moresco et al. 2012

Interpolate H(z) from a set of H i in redshift Apparent magnitude of SNeIa: Assumption: metric theory of gravity (fairly model independent) Straightforward to add curvature

Bayesian inference MCMC Affine invariant MCMC ensemble sampling (Goodman & Weare 2010) H(z)H(z)

It is reasonable to assume that H(z) increases with redshift, i.e., dH(z)/dz ≥ 0 or H i ≤ H i+1 Observations are largely consistent with such an assumption. Moresco et al.(2012)

Cosmological parameters of mock samples: WFIRST SNeIa error models: Sample size: 2725 z_max: 1.7

--- without MP --- with MP

without mono. prior with mono. prior

* DESI LSST: distances from H i  constraints on H i

Reconstruction of time-varying cosmological quantities is useful for model testing and cross checks. The monotonicity prior can significantly reduce the errors in reconstructed H i when the data is poor. Similar priors may be designed for other quantities of interest. The Hubble parameter can be constrained to a few percent level with multiple surveys under construction. SNeIa provide the best precision at z<0.5, and other methods will extend the measurements above z=2.