Publications

Harms, Gary A.; Knief, Ronald A.; Adams, Susan S.; Cole, Kerstan S.; Ford, John T.; Campbell, Rafe C.; Monahan, Shean P.

Abstract not provided.

Haass, Michael J.; Burnham, Laurie B.; Cole, Kerstan S.; Jeffers, Robert F.; Adams, Susan S.; Warrender, Christina E.; Forsythe, James C.

Abstract not provided.

Adams, Susan S.; Cole, Kerstan S.; Haass, Michael J.; Warrender, Christina E.; Jeffers, Robert F.; Burnham, Laurie B.; Forsythe, James C.

Abstract not provided.

Harms, Gary A.; Knief, Ronald A.; Adams, Susan S.; Cole, Kerstan S.; Ford, John T.; Campbell, Rafe C.

Abstract not provided.

Harms, Gary A.; Monahan, Shean P.; Knief, Ronald A.; Adams, Susan S.; Cole, Kerstan S.; Ford, John T.; Campbell, Rafe C.

Abstract not provided.

Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

McNamara, Laura A.; Cole, Kerstan S.; Haass, Michael J.; Matzen, Laura E.; Morrow, James D.; Adams, Susan S.; McMichael, Stephanie N.

Researchers at Sandia National Laboratories are integrating qualitative and quantitative methods from anthropology, human factors and cognitive psychology in the study of military and civilian intelligence analyst workflows in the United States’ national security community. Researchers who study human work processes often use qualitative theory and methods, including grounded theory, cognitive work analysis, and ethnography, to generate rich descriptive models of human behavior in context. In contrast, experimental psychologists typically do not receive training in qualitative induction, nor are they likely to practice ethnographic methods in their work, since experimental psychology tends to emphasize generalizability and quantitative hypothesis testing over qualitative description. However, qualitative frameworks and methods from anthropology, sociology, and human factors can play an important role in enhancing the ecological validity of experimental research designs.

Procedia Manufacturing

Adams, Susan S.; Cole, Kerstan S.; Haass, Michael J.; Warrender, Christina E.; Jeffers, Robert F.; Burnham, Laurie B.; Forsythe, James C.

Electric distribution utilities, the companies that feed electricity to end users, are overseeing a technological transformation of their networks, installing sensors and other automated equipment, that are fundamentally changing the way the grid operates. These grid modernization efforts will allow utilities to incorporate some of the newer technology available to the home user – such as solar panels and electric cars – which will result in a bi-directional flow of energy and information. How will this new flow of information affect control room operations? How will the increased automation associated with smart grid technologies influence control room operators’ decisions? And how will changes in control room operations and operator decision making impact grid resilience? These questions have not been thoroughly studied, despite the enormous changes that are taking place. In this study, which involved collaborating with utility companies in the state of Vermont, the authors proposed to advance the science of control-room decision making by understanding the impact of distribution grid modernization on operator performance. Distribution control room operators were interviewed to understand daily tasks and decisions and to gain an understanding of how these impending changes will impact control room operations. Situation awareness was found to be a major contributor to successful control room operations. However, the impact of growing levels of automation due to smart grid technology on operators’ situation awareness is not well understood. Future work includes performing a naturalistic field study in which operator situation awareness will be measured in real-time during normal operations and correlated with the technological changes that are underway. The results of this future study will inform tools and strategies that will help system operators adapt to a changing grid, respond to critical incidents and maintain critical performance skills.

Procedia Manufacturing

Haass, Michael J.; Warrender, Christina E.; Burnham, Laurie B.; Jeffers, Robert F.; Adams, Susan S.; Cole, Kerstan S.; Forsythe, James C.

The impact of automation on human performance has been studied by human factors researchers for over 35 years. One unresolved facet of this research is measurement of the level of automation across and within engineered systems. Repeatable methods of observing, measuring and documenting the level of automation are critical to the creation and validation of generalized theories of automation's impact on the reliability and resilience of human-in-the-loop systems. Numerous qualitative scales for measuring automation have been proposed. However these methods require subjective assessments based on the researcher's knowledge and experience, or through expert knowledge elicitation involving highly experienced individuals from each work domain. More recently, quantitative scales have been proposed, but have yet to be widely adopted, likely due to the difficulty associated with obtaining a sufficient number of empirical measurements from each system component. Our research suggests the need for a quantitative method that enables rapid measurement of a system's level of automation, is applicable across domains, and can be used by human factors practitioners in field studies or by system engineers as part of their technical planning processes. In this paper we present our research methodology and early research results from studies of electricity grid distribution control rooms. Using a system analysis approach based on quantitative measures of level of automation, we provide an illustrative analysis of select grid modernization efforts. This measure of the level of automation can be displayed as either a static, historical view of the system's automation dynamics (the dynamic interplay between human and automation required to maintain system performance) or it can be incorporated into real-time visualization systems already present in control rooms.

McNamara, Laura A.; Cole, Kerstan S.; Adams, Susan S.

Abstract not provided.

McNamara, Laura A.; Cole, Kerstan S.; Adams, Susan S.

Abstract not provided.

Adams, Susan S.; Cole, Kerstan S.; McNamara, Laura A.

Abstract not provided.

Burnham, Laurie B.; Warrender, Christina E.; Cole, Kerstan S.; Forsythe, James C.; Haass, Michael J.; Adams, Susan S.

Abstract not provided.

Warrender, Christina E.; Cole, Kerstan S.; Forsythe, James C.; Haass, Michael J.; Adams, Susan S.

Abstract not provided.

Burnham, Laurie B.; Warrender, Christina E.; Cole, Kerstan S.; Forsythe, James C.; Haass, Michael J.; Adams, Susan S.

Abstract not provided.

Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

Cole, Kerstan S.; Adams, Susan S.; McNamara, Laura A.; Ganter, John H.

The purpose of the current study was to analyze the work of imagery analysts associated with Sagebrush, a Synthetic Aperture Radar (SAR) imaging system, using an adapted version of cognitive work analysis (CWA). This was achieved by conducting a work domain analysis (WDA) for the system under consideration. Another purpose of this study was to describe how we adapted the WDA framework to include a sequential component and a means to explicitly represent relationships between components. Lastly, we present a simplified work domain representation that we have found effective in communicating the importance of analysts' adaptive strategies to inform the research strategies of computational science researchers who want to develop useful algorithms, but who have little or no familiarity with sensor data analysis work. © 2014 Springer International Publishing.

Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

Adams, Susan S.; Cole, Kerstan S.; McNamara, Laura A.

Imagery analysts are given the difficult task of determining, post-hoc, if particular events of importance had occurred, employing Synthetic Aperture Radar (SAR) images, written reports and PowerPoint presentations to make their decision. We were asked to evaluate the current system analysis process and make recommendations for a future temporal geospatial analysis prototype that is envisioned to allow analysts to quickly search for temporal and spatial relationships between image-derived features. As such, we conducted a Hierarchical task analysis (HTA; [3], [6]) to understand the analysts' tasks and subtasks. We also implemented a timeline analysis and workload assessment [4] to better understand which tasks were the most time-consuming and perceived as the most effortful. Our results gave the team clear recommendations and requirements for a prototype. © 2014 Springer International Publishing.

Cole, Kerstan S.; Trumbo, Michael C.; Adams, Susan S.; Matzen, Laura E.; Forsythe, James C.

Abstract not provided.

Morrow, James D.; Cole, Kerstan S.

Abstract not provided.

Communications in Computer and Information Science

Bandlow, Alisa; Matzen, Laura E.; Cole, Kerstan S.; Dornburg, Courtney S.; Geiseler, Charles J.; Greenfield, John A.; McNamara, Laura A.; Adams, Susan S.

Information visualization tools are being promoted to aid decision support. These tools assist in the analysis and comprehension of ambiguous and conflicting data sets. Formal evaluations are necessary to demonstrate the effectiveness of visualization tools, yet conducting these studies is difficult. Objective metrics that allow designers to compare the amount of work required for users to operate a particular interface are lacking. This in turn makes it difficult to compare workload across different interfaces, which is problematic for complicated information visualization and visual analytics packages. We believe that measures of working memory load can provide a more objective and consistent way of assessing visualizations and user interfaces across a range of applications. We present initial findings from a study using measures of working memory load to compare the usability of two graph representations. © 2011 Springer-Verlag.

Matzen, Laura E.; Cole, Kerstan S.; Dornburg, Courtney S.; Bandlow, Alisa B.; Gieseler, Charles J.; McNamara, Laura A.; Adams, Susan S.

Abstract not provided.

Bandlow, Alisa B.; Cole, Kerstan S.; McNamara, Laura A.; Dornburg, Courtney S.; Adams, Susan S.; Matzen, Laura E.; Gieseler, Charles J.

Abstract not provided.

Bandlow, Alisa B.; Matzen, Laura E.; Cole, Kerstan S.; Dornburg, Courtney S.; Gieseler, Charles J.; McNamara, Laura A.; Adams, Susan S.

Abstract not provided.

McNamara, Laura A.; Cole, Kerstan S.; Bandlow, Alisa B.; Dornburg, Courtney S.; Bauer, Travis L.

Abstract not provided.