# A fresh look at effect aliasing and interactions: some new wine in old   bottles

**Authors:** C. F. Jeff Wu

arXiv: 1703.02113 · 2017-07-12

## TL;DR

This paper introduces a novel approach to resolving effect aliasing in experimental designs through reparametrization and effect non-orthogonality, enabling better effect estimation in various fractional factorial designs.

## Contribution

It presents a new method for de-aliasing effects in fractional factorial designs by reparametrization and exploiting non-orthogonality, applicable to multiple design classes.

## Key findings

- Reparametrization resolves effect aliasing in regular and nonregular designs.
- Conditional main effects facilitate effect estimation in two-level designs.
- The approach extends to observational data using bi-level variable selection.

## Abstract

Interactions and effect aliasing are among the fundamental concepts in experimental design. In this paper, some new insights and approaches are provided on these subjects. In the literature, the "de-aliasing" of aliased effects is deemed to be impossible. We argue that this "impossibility" can indeed be resolved by employing a new approach which consists of reparametrization of effects and exploitation of effect non-orthogonality. This approach is successfully applied to three classes of designs: regular and nonregular two-level fractional factorial designs, and three-level fractional factorial designs. For reparametrization, the notion of conditional main effects (cme's) is employed for two-level regular designs, while the linear-quadratic system is used for three-level designs. For nonregular two-level designs, reparametrization is not needed because the partial aliasing of their effects already induces non-orthogonality. The approach can be extended to general observational data by using a new bi-level variable selection technique based on the cme's. A historical recollection is given on how these ideas were discovered.

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Source: https://tomesphere.com/paper/1703.02113