Differential Equation-Constrained Local Regression for Data with Sparse Design

TL;DR

This paper introduces a differential equation-constrained local regression method that improves data estimation in sparse regions by integrating differential equations, demonstrated on noisy tumor growth data.

Contribution

It develops a nonparametric regression approach leveraging differential equations to enhance local constant regression in sparse data areas.

Findings

Improved estimation accuracy in sparse data regions.

Effective application to noisy tumor growth data.

Comparison shows advantages over traditional methods.

Abstract

Local polynomial regression of order one or higher often performs poorly in areas with sparse data. In contrast, local constant regression tends to be more robust in these regions, although it is generally the least accurate approach, especially near the boundaries of the data. Incorporating information from differential equations, which may approximately or exactly hold, is one way of extending the sparse design capacity of local constant regression while reducing bias and variance. A nonparametric regression method that exploits first-order differential equations is studied in this paper and applied to noisy mouse tumour growth data. Asymptotic biases and variances of kernel estimators using Taylor polynomials with different degrees are discussed. Model comparison is performed for different estimators through simulation studies under various scenarios that simulate exponential-type growth.