Choice of Scoring Rules for Indirect Elicitation of Properties with Parametric Assumptions

TL;DR

This paper investigates how the choice of weights in combined proper scoring rules affects the estimation of properties with parametric assumptions, revealing that optimal weights often favor zeroing some weights and providing theoretical insights.

Contribution

It introduces a theoretical framework for understanding the impact of weight choices in indirect property elicitation using proper scoring rules under parametric models.

Findings

Optimal weights often involve setting some weights to zero.

Monotonic relationship between weights and estimation accuracy.

Theoretical conditions for two and multiple sub-properties.

Abstract

People are commonly interested in predicting a statistical property of a random event such as mean and variance. Proper scoring rules assess the quality of predictions and require that the expected score gets uniquely maximized at the precise prediction, in which case we call the score directly elicits the property. Previous research work has widely studied the existence and the characterization of proper scoring rules for different properties, but little literature discusses the choice of proper scoring rules for applications at hand. In this paper, we explore a novel task, the indirect elicitation of properties with parametric assumptions, where the target property is a function of several directly-elicitable sub-properties and the total score is a weighted sum of proper scoring rules for each sub-property. Because of the restriction to a parametric model class, different settings for the weights lead to different constrained optimal solutions. Our goal is to figure out how the choice of weights affects the estimation of the target property and which choice is the best. We start it with simulation studies and observe an interesting pattern: in most cases, the optimal estimation of the target property changes monotonically with the increase of each weight, and the best configuration of weights is often to set some weights as zero. To understand how it happens, we first establish the elementary theoretical framework and then provide deeper sufficient conditions for the case of two sub-properties and of more sub-properties respectively. The theory on 2-D cases perfectly interprets the experimental results. In higher-dimensional situations, we especially study the linear cases and suggest that more complex settings can be understood with locally mapping into linear situations or using linear approximations when the true values of sub-properties are close enough to the parametric space.