The problem state: A cognitive bottleneck in multitasking.

Borst, Jelmer P.; Taatgen, Niels; Rijn, Hedderik van

doi:10.1037/a0018106

Cited by 140 publications

(162 citation statements)

References 64 publications

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“…Consequently, if a model has to keep track of more than one piece of information, it has to move the pieces of information back and forth between two important modules: declarative memory and the problem state. Moving information back and forth comes with a time cost, and could cause a so-called cognitive bottleneck (Borst et al 2010). …”

Section: Act-r Modelingmentioning

confidence: 99%

Strategic Reasoning: Building Cognitive Models from Logical Formulas

Ghosh

Meijering

Verbrugge

2014

J of Log Lang and Inf

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This paper presents an attempt to bridge the gap between logical and cognitive treatments of strategic reasoning in games. There have been extensive formal debates about the merits of the principle of backward induction among game theorists and logicians. Experimental economists and psychologists have shown that human subjects, perhaps due to their bounded resources, do not always follow the backward induction strategy, leading to unexpected outcomes. Recently, based on an eye-tracking study, it has turned out that even human subjects who produce the outwardly correct 'backward induction answer' use a different internal reasoning strategy to achieve it. The paper presents a formal language to represent different strategies on a finer-grained level than was possible before. The language and its semantics help to precisely distinguish different cognitive reasoning strategies, that can then be tested on the basis of computational cognitive models and experiments with human subjects. The syntactic framework of the formal system provides a generic way of constructing computational cognitive models of the participants of the Marble Drop game.

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Section: Act-r Modelingmentioning

confidence: 99%

Strategic Reasoning: Building Cognitive Models from Logical Formulas

Ghosh

Meijering

Verbrugge

2014

J of Log Lang and Inf

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“…Its function is similar to the focus of attention in current working memory theories (17), and it can hold only one coherent chunk of information (18). We use the problem state module to locate working memory updates.…”

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confidence: 99%

Using model-based functional MRI to locate working memory updates and declarative memory retrievals in the fronto-parietal network

Borst

Anderson

2013

Proc. Natl. Acad. Sci. U.S.A.

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In this study, we used model-based functional MRI (fMRI) to locate two functions of the fronto-parietal network: declarative memory retrievals and updating of working memory. Because regions in the fronto-parietal network are by definition coherently active, locating functions within this network is difficult. To overcome this problem, we applied model-based fMRI, an analysis method that uses predictions of a computational model to inform the analysis. We applied model-based fMRI to five previously published datasets with associated computational cognitive models, and subsequently integrated the results in a meta-analysis. The meta-analysis showed that declarative memory retrievals correlated with activity in the inferior frontal gyrus and the anterior cingulate, whereas updating of working memory corresponded to activation in the inferior parietal lobule, as well as to activation around the inferior frontal gyrus and the anterior cingulate.I n this study, we used model-based functional MRI (fMRI) to locate two functions of the so-called "fronto-parietal network." The fronto-parietal network consists of brain areas that are coherently active and assumed to implement cognitive control functions: working memory, attentional selection, and error monitoring (1-5). It typically involves at least the dorsolateral prefrontal cortex, the anterior cingulate, and a region around the intraparietal sulcus. Because the regions in the fronto-parietal network are by definition active at the same time, distinguishing the precise functional characteristics of those regions is difficult with conventional fMRI methods. Model-based fMRI is particularly well suited for dissociating between highly correlated contributions to the blood oxygen level-dependent (BOLD) signal. We used model-based fMRI to locate two functions within the fronto-parietal network: declarative memory retrieval and updating of working memory. These functions are often assumed to be part of the fronto-parietal network, but the hypothesized locations within the network differ among studies (2, 6-11).Model-based fMRI is a relatively recent approach to analyzing fMRI data. Instead of using the condition structure of the experiment to inform the analysis, as in a conventional fMRI analysis, model-based fMRI uses information derived from a computational model (12, 13). For example, Daw et al. (14) fitted a mathematical reinforcement learning model to the behavior of their study participants and then used parameter values of the model as regressors in the fMRI analysis. This resulted in brain regions that correlated significantly with those parameter values, and thus with certain features of their model. Another recent study showed that modelbased fMRI can be used successfully in combination with more high-level information-processing models (15). By regressing the activity of model components (e.g., visual processing, declarative memory retrieval) against neural activity, the neural correlates of the model components can be located.To identify the neural correlates o...

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“…Multiple threads can be active at the same time, for example, we can easily drive a car (thread one) and listen to the radio (thread two) at the same time, as also evident from multiple resource theory [19]. Next to the socalled central procedural resource, which coordinates the execution of multiple threads, these threads can make use of various 'peripheral resources,' such as visual resources, motor resources or memory resources [20]. As described by threaded cognition theory [18], each particular resource can only be used by one thread at a time.…”

Section: Divided Attention and Multitasking Theorymentioning

confidence: 99%

“…For example, since one can only look at one visual object at the time, a person who is driving while using a navigation system can only look at either the road or the navigation system's display. When both require visual attention, a bottleneck [20] occurs and one of these two threads must wait before the visual resource is free. Therefore, the extent to which two activities can be performed in parallel depends on their stage of execution and the particular resources they require.…”

Section: Divided Attention and Multitasking Theorymentioning

confidence: 99%

Peripheral interaction: characteristics and considerations

Bakker

Hoven

Eggen

2014

Pers Ubiquit Comput

118

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In everyday life, we are able to perceive information and perform physical actions in the background or periphery of attention. Inspired by this observation, several researchers have studied interactive systems that display digital information in the periphery of attention. To broaden the scope of this research direction, a few recent studies have focused on interactive systems that can not only be perceived in the background but also enable users to physically interact with digital information in their periphery. Such peripheral interaction designs can support computing technology to fluently embed in and become a meaningful part of people's everyday routines. With the increasing ubiquity of technology in our everyday environment, we believe that this direction is highly relevant nowadays. This paper presents an in-depth analysis of three case studies on peripheral interaction. These case studies involved the design and development of peripheral interactive systems and deployment of these systems in the real context of use for a number of weeks. Based on the insights gained through these case studies, we discuss generalized characteristics and considerations for peripheral interaction design and evaluation. The aim of the work presented in this paper is to support interaction design researchers and practitioners in anticipating and facilitating peripheral interaction with the designs they are evaluating or developing.

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The problem state: A cognitive bottleneck in multitasking.

Cited by 140 publications

References 64 publications

Strategic Reasoning: Building Cognitive Models from Logical Formulas

Strategic Reasoning: Building Cognitive Models from Logical Formulas

Using model-based functional MRI to locate working memory updates and declarative memory retrievals in the fronto-parietal network

Peripheral interaction: characteristics and considerations

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