The scientific theme of this research program is investigating connecting the human element with the emerging digital manufacturing enterprise (i.e., Industrial Internet of Things), quantifying physical and mental human behaviors and their uncertainty, and investigating the effect of human-integrated digital technologies as both information generators and feedback mechanisms on attitudes and performance in the manufacturing enterprise.

The objectives are to first understand the quality of information that becomes available through human-based data capture and analysis technologies, including uncertainty distributions, then investigate means of feeding back digital information to human agents in order to assess the effect on human performance and the overall manufacturing system metrics.

This research addresses limitations of current forming, machining, and joining processes through energy augmentation. Electric current supply is incorporated to equipment and fixture designs, and controls developed to actively modulate metallic material properties during processing. Results are the ability to process thicker, stronger materials at a higher rate with improved quality control.

In this area we model process parameters’ effect on wear and cutting forces, and the subsequent cumulative effect on the plastic deformation zone depth (which we term the Machining Affected Zone, MAZ) through a stochastic representation approach, whereby model parameters are represented not as scalar constants but rather as random-variable belief distributions. We use optimal state estimators and a Bayesian updating approach for modifying the model beliefs based on limited observational data. The resultant models are used in a numeric milling simulation to predict the shape and evolution of tool wear, and stochastic beliefs on stability. The sum of the knowledge generated is applied to deriving robust tool paths for improving the consistency and performance of the process.

A unique aspect to the experimental validation side of the investigation is our approach termed contrived tool wear. With this approach, the nominal wear shape under a given set of conditions is ground into a new set of cutting tools, so repeatability of the worn tool force and MAZ depth model can be decoupled from the tool wear variability itself. Through this approach, we gain insight into the force, machining affected zone, and stability progression independent from the tool wear variability.