Isotonic Regression in Multi-Dimensional Spaces and Graphs

Abstract

In this paper we study minimax and adaptation rates in general isotonic regression. For uniform deterministic and random designs in [0,1]d with d 2 and N(0,1) noise, the minimax rate for the 2 risk is known to be bounded from below by n-1/d when the unknown mean function f is nondecreasing and its range is bounded by a constant, while the least squares estimator (LSE) is known to nearly achieve the minimax rate up to a factor ( n)γ where n is sample size, γ = 4 in the lattice design and γ = \9/2, (d2+d+1)/2 \ in the random design. Moreover, the LSE is known to achieve the adaptation rate (K/n)-2/d\1 (n/K)\2γ when f is piecewise constant on K hyperrectangles in a partition of [0,1]d. Due to the minimax theorem, the LSE is identical on every design point to both the max-min and min-max estimators over all upper and lower sets containing the design point. This motivates our consideration of estimators which lie in-between the max-min and min-max estimators over possibly smaller classes of upper and lower sets, including a subclass of block estimators. Under a q-th moment condition on the noise, we develop q risk bounds for such general estimators for isotonic regression on graphs. For uniform deterministic and random designs in [0,1]d with d 3, our 2 risk bound for the block estimator matches the minimax rate n-1/d when the range of f is bounded and achieves the near parametric adaptation rate (K/n)\1(n/K)\d when f is K-piecewise constant. Furthermore, the block estimator possesses the following oracle property in variable selection: When f depends on only a subset S of variables, the 2 risk of the block estimator automatically achieves up to a poly-logarithmic factor the minimax rate based on the oracular knowledge of S.