P-B designs have some advantages over regular FF designs, including the design size increasing four runs at a time instead of doubling. On the other hand, they have correlated effects, which puts off some experimenters. I see this as an advantage. I can estimate correlated parameters, albeit with inflated variance. I cannot estimate confounded effects via an FF design. I eliminate model bias if I estimate correlated terms. I suffer model bias if I exclude confounded terms. The fold-over runs will reduce the correlations when using the P-B design, as they reduce the confounding with FF designs.

Hi @SaraA,

I'm not sure I fully understand your question, but I will provide a first discussion starter.

• Plackett-Burman are usually Resolution III screening design, meaning that main effects are correlated with 2-factors interactions. Only main effects are estimable with some precision (without correlations between each others and with the assumption that interactions and higher order terms are negligible).
• Resolution is a measure of the degree of confounding in an experimental design (Resolution in Screening Designs):
  • Resolution III means that some main effects are confounded with one or more two-factor interactions. In order for the main effects to be meaningful, these interactions must be assumed to be negligible.
  • Resolution IV means that main effects are not confounded with other main effects or two-factor interactions. However, some two-factor interactions are confounded with other two-factor interactions.
  • Resolution V means that there is no confounding between main effects, between main effects and two-factor interactions, and between pairs of two-factor interactions. Some two-factor interactions are confounded with three-factor interactions.
  • Resolution V+ means that the design has resolution greater than 5 but is not a full factorial design.
  • Resolution VI means that there is no confounding between effects of any order. The design is a full factorial design.
• Plackett-Burman designs are efficient screening design for main effects, but may need augmentation to augment main effects estimates precision and to investigate 2-factors interactions (and other higher order terms). In order to do this, you can :
  • Augment your design and specify a model, so that the platform will optimally augment your initial PB screening design with new runs to be able to estimate the new terms added in the model : Example Using the Augment Design Platform
  • Augment your design by doing a foldover. This create the same additional number of runs of the original design with the same values for the factors, except for the factor over which the foldover is done, the new runs will have values mirroring the initial set (-1 instead of 1, 1 instead of -1, rest of the factors values stay the same). This is helpful to remove the confounding of two-factor interactions and main effects : Create a Foldover Design

As different designs may be helpful depending on the situation, I can only suggest to try creating several designs and compare them before choosing one and doing the experiments.
As a general remark, the higher the resolution, the higher the number of runs required, so you need to evaluate the tradeoff between what you want to discover/evaluate and your experimental budget constraint. Also depending on the construction and type of classical design (fractional factorial, Plackett-Burman or others) you may not have a lot of flexibility on the run size step/increment (as an example, here is the possible designs list for 5 factors from the 2-levels screening design platform) :

You may find a higher flexibility in run size, model specification, and better handling of constraints by using the Custom Design platform.

Hope this first discussion starter may help you,