+
+The above mentioned application is one of many examples (e.g., mass spectrography \cite{Kearsley_2006} and global warming data \cite{Yohai}) where univariate data needs to be fitted by monotonicity preserving interpolants. Of course, CDF is a monotone increasing function, whose inverse, called quantile function, can be used to calculate the quantiles. Spline interpolation would be the most suitable nonparametric method to fit the CDF, except that polynomial splines do not preserve monotonicity of the data, as illustrated on Figure \ref{ch11:fig1}.
+
+
+The failure of splines to preserve monotonicity has prompted fundamental research in this area since the 1960s. One of the first methods to remedy this problem was splines in tension by Schweikert \cite{Sch}, where a tension parameter controlled the shape of exponential splines \cite{Spath1969}. Later on several monotonicity preserving polynomial spline algorithms were proposed \cite{Schumaker1983,PasRoul1977,AndElf1987,Andersson1991_JAT,McAllister1981_ACM}. These algorithms typically rely on introducing additional spline knots between the abscissae of the data. Algorithmic developments are active to this day; see, for example, \cite{Kvasov2000_book,Abbas2011}.
+
+When in addition to the pairs $(x_i, y_i)$ the slopes of the function are available, i.e., the data comes in triples $(x_i, y_i, p_i)$, the interpolation problem is called Hermite, and the Hermite splines are used. However, even when the sequence $y_i$ is increasing and the slopes $p_i$ are nonnegative, cubic Hermite splines may still fail to be monotone, as illustrated in Figure \ref{ch11:fig2}. Thus, monotone Hermite splines are needed \cite{Gregory1982}. \index{Hermite splines}
+
+Another issue with monotone approximation is noisy data. In this case inaccuracies in the data make the input sequence $y_i$ itself nonmonotone; and hence monotone spline interpolation algorithms will fail. Monotone spline smoothing algorithms are available, e.g., \cite{Andersson1991_JAT,Elfving1989_NM}. Such algorithms are based on solving a quadratic (or another convex) programming problem numerically, and have not yet been adapted to parallel processing.
+
+In this work we examine several monotone spline fitting algorithms, and select the ones that we believe are most suitable for parallelization on GPUs. We pay attention to numerical efficiency in terms of numerical calculations and memory access pattern, and favor one-pass algorithms. We also look at smoothing noisy data and developed a parallel version of the Minimum Lower Sets (MLS) algorithm for the isotonic regression problem \cite{Best1990, Robertson_book}.
+\index{isotone regression}
+
+The rest of the chapter is organized as follows. Section \ref{ch11:splines} discusses monotone spline interpolation methods and presents two parallel algorithms. Section \ref{ch11:smoothing} deals with the smoothing problem. It presents the isotonic regression problem and discusses the Pool Adjacent Violators (PAV) and MLS algorithms. Combined with monotone spline interpolation, the parallel MLS method makes it possible to build a monotone spline approximation to noisy data entirely on GPU. Section \ref{ch11:conc} concludes.
+
+\clearpage