Investigating the generalizability of EEG-based Cognitive Load Estimation Across Visualizations

We examine if EEG-based cognitive load (CL) estimation is generalizable across the character, spatial pattern, bar graph and pie chart-based visualizations for the nback~task. CL is estimated via two recent approaches: (a) Deep convolutional neural network, and (b) Proximal support vector machines. Experiments reveal that CL estimation suffers across visualizations motivating the need for effective machine learning techniques to benchmark visual interface usability for a given analytic task

THE ROLE OF EMOTION IN VISUALIZATION

The popular notion that emotion and reason are incompatible is no longer defensi- ble. Recent research in psychology and cognitive science has established emotion as a key element in numerous aspects of perception and cognition, including attention, memory, decision-making, risk perception, and creativity. This dissertation centers around the observation that emotion influences many aspects of perception and cog- nition that are crucial for effective visualization. First, I demonstrate that emotion influences accuracy in fundamental visualiza- tion tasks by combining a classic graphical perception experiment (from Cleveland and McGill) with emotion induction procedures from psychology (chapter 3). Next, I expand on the experiments in the first chapter to explore additional techniques for studying emotion and visualization, resulting in an experiment that shows that performance differences between primed individuals persist even as task difficulty in- creases (chapter 4). In a separate experiment, I show how certain emotional states (i.e. frustration and engagement) can be inferred from visualization interaction logs using machine learning (chapter 5). I then discuss a model for individual cognitive dif- ferences in visualization, which situates emotion into existing individual differences research in visualization (chapter 6). Finally, I propose an preliminary model for emotion in visualization (chapter 7)

Task switching in the prefrontal cortex

The overall goal of this dissertation is to elucidate the cellular and circuit mechanisms underlying flexible behavior in the prefrontal cortex. We are often faced with situations in which the appropriate behavior in one context is inappropriate in others. If these situations are familiar, we can perform the appropriate behavior without relearning how the context relates to the behavior — an important hallmark of intelligence. Neuroimaging and lesion studies have shown that this dynamic, flexible process of remapping context to behavior (task switching) is dependent on prefrontal cortex, but the precise contributions and interactions of prefrontal subdivisions are still unknown. This dissertation investigates two prefrontal areas that are thought to be involved in distinct, but complementary executive roles in task switching — the dorsolateral prefrontal cortex (dlPFC) and the anterior cingulate cortex (ACC). Using electrophysiological recordings from macaque monkeys, I show that synchronous network oscillations in the dlPFC provide a mechanism to flexibly coordinate context representations (rules) between groups of neurons during task switching. Then, I show that, wheras the ACC neurons can represent rules at the cellular level, they do not play a significant role in switching between contexts — rather they seem to be more related to errors and motivational drive. Finally, I develop a set of web-enabled interactive visualization tools designed to provide a multi-dimensional integrated view of electrophysiological datasets. Taken together, these results contribute to our understanding of task switching by investigating new mechanisms for coordination of neurons in prefrontal cortex, clarifying the roles of prefrontal subdivisions during task switching, and providing visualization tools that enhance exploration and understanding of large, complex and multi-scale electrophysiological data

Embedding mobile learning into everyday life settings

The increasing ubiquity of smartphones has changed the way we interact with information and acquire new knowledge. The prevalence of personal mobile devices in our everyday lives creates new opportunities for learning that exceed the narrow boundaries of a school’s classroom and provide the foundations for lifelong learning. Learning can now happen whenever and wherever we are; whether on the sofa at home, on the bus during our commute, or on a break at work. However, the flexibility offered by mobile learning also creates its challenges. Being able to learn anytime and anywhere does not necessarily result in learning uptake. Without the school environment’s controlled schedule and teacher guidance, the learners must actively initiate learning activities, keep up repetition schedules, and cope with learning in interruption-prone everyday environments. Both interruptions and infrequent repetition can harm the learning process and long-term memory retention. We argue that current mobile learning applications insufficiently support users in coping with these challenges. In this thesis, we explore how we can utilize the ubiquity of mobile devices to ensure frequent engagement with the content, focusing primarily on language learning and supporting users in dealing with learning breaks and interruptions. Following a user-centered design approach, we first analyzed mobile learning behavior in everyday settings. Based on our findings, we proposed concepts and designs, developed research prototypes, and evaluated them in laboratory and field evaluations with a specific focus on user experience. To better understand users’ learning behavior with mobile devices, we first characterized their interaction with mobile learning apps through a detailed survey and a diary study. Both methods confirmed the enormous diversity in usage situations and preferences. We observed that learning often happens unplanned, infrequently, among the company of friends or family, or while simultaneously performing secondary tasks such as watching TV or eating. The studies further uncovered a significant prevalence of interruptions in everyday settings that affected users’ learning behavior, often leading to suspension and termination of the learning activities. We derived design implications to support learning in diverse situations, particularly aimed at mitigating the adverse effects of multitasking and interruptions. The proposed strategies should help designers and developers create mobile learning applications that adapt to the opportunities and challenges of learning in everyday mobile settings. We explored four main challenges, emphasizing that (1) we need to consider that Learning in Everyday Settings is Diverse and Interruption-prone, (2) learning performance is affected by Irregular and Infrequent Practice Behavior, (3) we need to move From Static to Personalized Learning, and (4) that Interruptions and Long Learning Breaks can Negatively Affect Performance. To tackle these challenges, we propose to embed learning into everyday smartphone interactions, which could foster frequent engagement with – and implicitly personalize – learning content (according to users’ interests and skills). Further, we investigate how memory cues could be applied to support task resumption after interruptions in mobile learning. To confirm that our idea of embedding learning into everyday interactions can increase exposure, we developed an application integrating learning tasks into the smartphone authentication process. Since unlocking the smartphone is a frequently performed action without any other purpose, our subjects appreciated the idea of utilizing this process to perform quick and simple learning interactions. Evidence from a comparative user study showed that embedding learning tasks into the unlocking mechanism led to significantly more interactions with the learning content without impairing the learning quality. We further explored a method for embedding language comprehension assessment into users’ digital reading and listening activities. By applying physiological measurements as implicit input, we reliably detected unknown words during laboratory evaluations. Identifying such knowledge gaps could be used for the provision of in-situ support and to inform the generation of personalized language learning content tailored to users’ interests and proficiency levels. To investigate memory cueing as a concept to support task resumption after interruptions, we complemented a theoretical literature analysis of existing applications with two research probes implementing and evaluating promising design concepts. We showed that displaying memory cues when the user resumes the learning activity after an interruption improves their subjective user experience. A subsequent study presented an outlook on the generalizability of memory cues beyond the narrow use case of language learning. We observed that the helpfulness of memory cues for reflecting on prior learning is highly dependent on the design of the cues, particularly the granularity of the presented information. We consider interactive cues for specific memory reactivation (e.g., through multiple-choice questions) a promising scaffolding concept for connecting individual micro-learning sessions when learning in everyday settings. The tools and applications described in this thesis are a starting point for designing applications that support learning in everyday settings. We broaden the understanding of learning behavior and highlight the impact of interruptions in our busy everyday lives. While this thesis focuses mainly on language learning, the concepts and methods have the potential to be generalized to other domains, such as STEM learning. We reflect on the limitations of the presented concepts and outline future research perspectives that utilize the ubiquity of mobile devices to design mobile learning interactions for everyday settings.Die Allgegenwärtigkeit von Smartphones verändert die Art und Weise wie wir mit Informationen umgehen und Wissen erwerben. Die weite Verbreitung von mobilen Endgeräten in unserem täglichen Leben führt zu neuen Möglichkeiten des Lernens, welche über die engen Grenzen eines Klassenraumes hinausreichen und das Fundament für lebenslanges Lernen schaffen. Lernen kann nun zu jeder Zeit und an jedem Ort stattfinden: auf dem Sofa Zuhause, im Bus während des Pendelns oder in der Pause auf der Arbeit. Die Flexibilität des mobilen Lernens geht jedoch zeitgleich mit Herausforderungen einher. Ohne den kontrollierten Ablaufplan und die Unterstützung der Lehrpersonen im schulischen Umfeld sind die Lernenden selbst dafür verantwortlich, aktiv Lernsitzungen zu initiieren, Wiederholungszyklen einzuhalten und Lektionen in unterbrechungsanfälligen Alltagssituationen zu meistern. Sowohl Unterbrechungen als auch unregelmäßige Wiederholung von Inhalten können den Lernprozess behindern und der Langzeitspeicherung der Informationen schaden. Wir behaupten, dass aktuelle mobile Lernanwendungen die Nutzer*innen nur unzureichend in diesen Herausforderungen unterstützen. In dieser Arbeit erforschen wir, wie wir uns die Allgegenwärtigkeit mobiler Endgeräte zunutze machen können, um zu erreichen, dass Nutzer*innen regelmäßig mit den Lerninhalten interagieren. Wir fokussieren uns darauf, sie im Umgang mit Unterbrechungen und Lernpausen zu unterstützen. In einem nutzerzentrierten Designprozess analysieren wir zunächst das Lernverhalten auf mobilen Endgeräten in alltäglichen Situationen. Basierend auf den Erkenntnissen schlagen wir Konzepte und Designs vor, entwickeln Forschungsprototypen und werten diese in Labor- und Feldstudien mit Fokus auf User Experience (wörtl. “Nutzererfahrung”) aus. Um das Lernverhalten von Nutzer*innen mit mobilen Endgeräten besser zu verstehen, versuchen wir zuerst die Interaktionen mit mobilen Lernanwendungen durch eine detaillierte Umfrage und eine Tagebuchstudie zu charakterisieren. Beide Methoden bestätigen eine enorme Vielfalt von Nutzungssituationen und -präferenzen. Wir beobachten, dass Lernen oft ungeplant, unregelmäßig, im Beisein von Freunden oder Familie, oder während der Ausübung anderer Tätigkeiten, beispielsweise Fernsehen oder Essen, stattfindet. Die Studien decken zudem Unterbrechungen in Alltagssituationen auf, welche das Lernverhalten der Nutzer*innen beeinflussen und oft zum Aussetzen oder Beenden der Lernaktivität führen. Wir leiten Implikationen ab, um Lernen in vielfältigen Situationen zu unterstützen und besonders die negativen Einflüsse von Multitasking und Unterbrechungen abzuschwächen. Die vorgeschlagenen Strategien sollen Designer*innen und Entwickler*innen helfen, mobile Lernanwendungen zu erstellen, welche sich den Möglichkeiten und Herausforderungen von Lernen in Alltagssituationen anpassen. Wir haben vier zentrale Herausforderungen identifiziert: (1) Lernen in Alltagssituationen ist divers und anfällig für Unterbrechungen; (2) Die Lerneffizienz wird durch unregelmäßiges Wiederholungsverhalten beeinflusst; (3) Wir müssen von statischem zu personalisiertem Lernen übergehen; (4) Unterbrechungen und lange Lernpausen können dem Lernen schaden. Um diese Herausforderungen anzugehen, schlagen wir vor, Lernen in alltägliche Smartphoneinteraktionen einzubetten. Dies führt zu einer vermehrten Beschäftigung mit Lerninhalten und könnte zu einer impliziten Personalisierung von diesen anhand der Interessen und Fähigkeiten der Nutzer*innen beitragen. Zudem untersuchen wir, wie Memory Cues (wörtl. “Gedächtnishinweise”) genutzt werden können, um das Fortsetzen von Aufgaben nach Unterbrechungen im mobilen Lernen zu erleichtern. Um zu zeigen, dass unsere Idee des Einbettens von Lernaufgaben in alltägliche Interaktionen wirklich die Beschäftigung mit diesen erhöht, haben wir eine Anwendung entwickelt, welche Lernaufgaben in den Entsperrprozess von Smartphones integriert. Da die Authentifizierung auf dem Mobilgerät eine häufig durchgeführte Aktion ist, welche keinen weiteren Mehrwert bietet, begrüßten unsere Studienteilnehmenden die Idee, den Prozess für die Durchführung kurzer und einfacher Lerninteraktionen zu nutzen. Ergebnisse aus einer vergleichenden Nutzerstudie haben gezeigt, dass die Einbettung von Aufgaben in den Entsperrprozess zu signifikant mehr Interaktionen mit den Lerninhalten führt, ohne dass die Lernqualität beeinträchtigt wird. Wir haben außerdem eine Methode untersucht, welche die Messung von Sprachverständnis in die digitalen Lese- und Höraktivitäten der Nutzer*innen einbettet. Mittels physiologischer Messungen als implizite Eingabe können wir in Laborstudien zuverlässig unbekannte Wörter erkennen. Die Aufdeckung solcher Wissenslücken kann genutzt werden, um in-situ Untestützung bereitzustellen und um personalisierte Lerninhalte zu generieren, welche auf die Interessen und das Wissensniveau der Nutzer*innen zugeschnitten sind. Um Memory Cues als Konzept für die Unterstützung der Aufgabenfortsetzung nach Unterbrechungen zu untersuchen, haben wir eine theoretische Literaturanalyse von bestehenden Anwendungen um zwei Forschungsarbeiten erweitert, welche vielversprechende Designkonzepte umsetzen und evaluieren. Wir haben gezeigt, dass die Präsentation von Memory Cues die subjektive User Experience verbessert, wenn der Nutzer die Lernaktivität nach einer Unterbrechung fortsetzt. Eine Folgestudie stellt einen Ausblick auf die Generalisierbarkeit von Memory Cues dar, welcher über den Tellerrand des Anwendungsfalls Sprachenlernen hinausschaut. Wir haben beobachtet, dass der Nutzen von Memory Cues für das Reflektieren über gelernte Inhalte stark von dem Design der Cues abhängt, insbesondere von der Granularität der präsentierten Informationen. Wir schätzen interaktive Cues zur spezifischen Gedächtnisaktivierung (z.B. durch Mehrfachauswahlfragen) als einen vielversprechenden Unterstützungsansatz ein, welcher individuelle Mikrolerneinheiten im Alltag verknüpfen könnte. Die Werkzeuge und Anwendungen, die in dieser Arbeit beschrieben werden, sind ein Startpunkt für das Design von Anwendungen, welche das Lernen in Alltagssituationen unterstützen. Wir erweitern das Verständnis, welches wir von Lernverhalten im geschäftigen Alltagsleben haben und heben den Einfluss von Unterbrechungen in diesem hervor. Während sich diese Arbeit hauptsächlich auf das Lernen von Sprachen fokussiert, haben die vorgestellten Konzepte und Methoden das Potential auf andere Bereiche übertragen zu werden, beispielsweise das Lernen von MINT Themen. Wir reflektieren über die Grenzen der präsentierten Konzepte und skizzieren Perspektiven für zukünftige Forschungsarbeiten, welche sich die Allgegenwärtigkeit von mobilen Endgeräten zur Gestaltung von Lernanwendungen für den Alltag zunutze machen

Master of Science

thesisThe current study utilized a meta-analysis review to investigate the sensitivity of several cognitive load measures. Specifically, the study examined whether self-rating, single-task performance, dual-task performance, eye-track, or physiological measures are most sensitive to changes in cognitive load. Additionally, the sensitivity of load measures was analyzed in relation to several variables such as age, research design, and learning content. After the initial search, 224 publications were identified and coded for inclusion in the meta-analysis. A random-effects model was employed, and the results demonstrated that cognitive load sensitivity varied by measure type. The load sensitivity among the study characteristics of age, content area, and research design also varied corresponding to specific cognitive load measure types. The number of self-rating items used to assess cognitive load did not significantly vary between single item and multiple item scales. Lastly, cognitive load sensitivity did not vary significantly among the measures in relation to peak and overall load. The last result may be biased by a small sample size of peak measures (n = 8)

Event-related desynchronization in motor imagery with EEG neurofeedback in the context of declarative interference and sleep

Motor imagery (MI) in combination with neurofeedback (NF) is a promising supplement to facilitate the acquisition of motor abilities and the recovery of impaired motor abilities following brain injuries. However, the ability to control MI NF is subject to a wide range of inter-individual variability. A substantial number of users experience difficulties in achieving good results, which compromises their chances to benefit from MI NF in a learning or rehabilitation context. It has been suggested that context factors, that is, factors outside the actual motor task, can explain individual differences in motor skill acquisition. Retrospective declarative interference and sleep have already been identified as critical factors for motor execution (ME) and MI based practice. Here, we investigate whether these findings generalize to practicing MI NF. Three groups underwent three blocks of practicing MI with NF, each on two subsequent days. In two of the groups, MI NF blocks were followed by either immediate or delayed declarative memory tasks. The control group performed only MI NF and no specific interference tasks. Two of the MI NF blocks were run on the first day of the experiment, the third in the morning of the second day. Significant within-block NF gains in mu and beta frequency event-related desynchronization (ERD) where evident for all groups. However, data did not provide evidence for an impact of immediate or delayed declarative interference on MI NF ERD. Also, MI NF ERD remained unchanged after a night of sleep. We did not observe the expected pattern of results for MI NF ERD with regard to declarative interference and a night of sleep. This is discussed in the context of variable experimental task designs, inter-individual differences, and performance measures

Breaking Down the Barriers To Operator Workload Estimation: Advancing Algorithmic Handling of Temporal Non-Stationarity and Cross-Participant Differences for EEG Analysis Using Deep Learning

This research focuses on two barriers to using EEG data for workload assessment: day-to-day variability, and cross- participant applicability. Several signal processing techniques and deep learning approaches are evaluated in multi-task environments. These methods account for temporal, spatial, and frequential data dependencies. Variance of frequency- domain power distributions for cross-day workload classification is statistically significant. Skewness and kurtosis are not significant in an environment absent workload transitions, but are salient with transitions present. LSTMs improve day- to-day feature stationarity, decreasing error by 59% compared to previous best results. A multi-path convolutional recurrent model using bi-directional, residual recurrent layers significantly increases predictive accuracy and decreases cross-participant variance. Deep learning regression approaches are applied to a multi-task environment with workload transitions. Accounting for temporal dependence significantly reduces error and increases correlation compared to baselines. Visualization techniques for LSTM feature saliency are developed to understand EEG analysis model biases

ELECTROPHYSIOLOGICAL MECHANISMS FOR PREPARING CONTROL IN TIME

Cognitive control is critical in guiding goal-directed behavior, preparing neural resources and adapting processing to promote optimal action in a given environment. According to the Dual Mechanisms of Control theory (Braver, 2012), control can be dichotomized into proactive and reactive modes of control, utilized reciprocally in ahead-of-time preparation versus last-minute, stimulus-evoked reaction. Although a substantial body of work has tested differences between proactive control and reactive control, the underlying assumption of proactive control as a unitary process has not been systematically investigated. Very little is known as to how or when proactive control is initiated, sustained, or implemented. As time is an integral building block of perception, cognition, and action (Buhusi & Meck, 2005), one should expect temporal information to be integrated into proactive control. Cognitive control is costly (Shenhav, Botvinick, & Cohen, 2013), and a temporally-guided modulation of control may offer substantial cost savings. By measuring proactive control on a sub-second time-scale, we can begin to gauge whether dissociable sub-types of proactive control are utilized demanding on temporal demands. Moreover, by comparing proactive control processes across different temporal demands, we can parse out when different aspects of control are computed and implemented. Through a meta-analytic review and three empirical experiments, this dissertation provides insight into how timing dynamics may influence the computation, maintenance, and instantiation of proactive cognitive control. First, a meta-analysis on the cued control literature reveals that seemingly trivial experimental parameters shape the use of proactive versus reactive control. Two EEG studies then demonstrate how modulating timing dynamics influences prefrontal mechanisms for preparatory cognitive control. In a final EEG study, we compare the mechanisms utilized to retain control goals versus visuo-spatial working memory items. Overall, this dissertation elucidates several novel electrophysiological mechanisms by which timing information is implemented in the computation and retention of cognitive control rules. Further, we provide evidence that individual differences in impulsivity and working memory shape distinct aspects of preparation. The findings reported here make clear that timing information is critical in guiding proactive control processes, and support a fundamental reconsideration of proactive control based on temporal dynamics