TY  - JOUR
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
T1  - Oculomotor control in a sequential search task
N2  - Using a serial search paradigm, we observed several effects of within-object fixation position on spatial and temporal control of eye movements: the preferred viewing location, launch site effect, the optimal viewing position, and the inverted optimal viewing position of fixation duration. While these effects were first identified by eye-movement studies in reading, our approach permits an analysis of the functional relationships between the effects in a different paradigm. Our results demonstrate that the fixation position is an important predictor of the subsequent saccade by influencing both fixation duration and the selection of the next saccade target.
Y1  - 2007
U6  - https://doi.org/10.1016/j.visres.2007.05.010
ER  - 
TY  - JOUR
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
T1  - ICAT: a computational model for the adaptive control of fixation durations
JF  - Psychonomic bulletin & review : a journal of the Psychonomic Society
N2  - Eye movements depend on cognitive processes related to visual information processing. Much has been learned about the spatial selection of fixation locations, while the principles governing the temporal control (fixation durations) are less clear. Here, we review current theories for the control of fixation durations in tasks like visual search, scanning, scene perception, and reading and propose a new model for the control of fixation durations. We distinguish two local principles from one global principle of control. First, an autonomous saccade timer initiates saccades after random time intervals (local-I). Second, foveal inhibition permits immediate prolongation of fixation durations by ongoing processing (local-II). Third, saccade timing is adaptive, so that the mean timer value depends on task requirements and fixation history (Global). We demonstrate by numerical simulations that our model qualitatively reproduces patterns of mean fixation durations and fixation duration distributions observed in typical experiments. When combined with assumptions of saccade target selection and oculomotor control, the model accounts for both temporal and spatial aspects of eye movement control in two versions of a visual search task. We conclude that the model provides a promising framework for the control of fixation durations in saccadic tasks.
KW  - Computational modeling
KW  - Eye movements
KW  - Adaptive control
KW  - Fixation duration
Y1  - 2014
U6  - https://doi.org/10.3758/s13423-013-0575-0
SN  - 1069-9384
SN  - 1531-5320
VL  - 21
IS  - 4
SP  - 907
EP  - 934
PB  - Springer
CY  - New York
ER  - 
TY  - JOUR
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
T1  - Eye movements in a sequential scanning task - evidence for distributed processing
JF  - Journal of vision
N2  - Current models of eye movement control are derived from theories assuming serial processing of single items or from theories based on parallel processing of multiple items at a time. This issue has persisted because most investigated paradigms generated data compatible with both serial and parallel models. Here, we study eye movements in a sequential scanning task, where stimulus n indicates the position of the next stimulus n + 1. We investigate whether eye movements are controlled by sequential attention shifts when the task requires serial order of processing. Our measures of distributed processing in the form of parafoveal-on-foveal effects, long-range modulations of target selection, and skipping saccades provide evidence against models strictly based on serial attention shifts. We conclude that our results lend support to parallel processing as a strategy for eye movement control.
KW  - eye movements
KW  - distributed processing
KW  - sequential attention shifts
KW  - parafoveal-on-foveal effects
KW  - skipping costs/benefits
Y1  - 2012
U6  - https://doi.org/10.1167/12.1.5
SN  - 1534-7362
VL  - 12
IS  - 1
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - JOUR
A1  - Trukenbrod, Hans Arne
A1  - Barthelme, Simon
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Spatial statistics for gaze patterns in scene viewing
BT  - effects of repeated viewing
JF  - Journal of vision
N2  - Scene viewing is used to study attentional selection in complex but still controlled environments. One of the main observations on eye movements during scene viewing is the inhomogeneous distribution of fixation locations: While some parts of an image are fixated by almost all observers and are inspected repeatedly by the same observer, other image parts remain unfixated by observers even after long exploration intervals. Here, we apply spatial point process methods to investigate the relationship between pairs of fixations. More precisely, we use the pair correlation function, a powerful statistical tool, to evaluate dependencies between fixation locations along individual scanpaths. We demonstrate that aggregation of fixation locations within 4 degrees is stronger than expected from chance. Furthermore, the pair correlation function reveals stronger aggregation of fixations when the same image is presented a second time. We use simulations of a dynamical model to show that a narrower spatial attentional span may explain differences in pair correlations between the first and the second inspection of the same image.
KW  - scene viewing
KW  - pair correlation function
KW  - spatial correlations
Y1  - 2019
U6  - https://doi.org/10.1167/19.6.5
SN  - 1534-7362
VL  - 19
IS  - 5
SP  - 1
EP  - 19
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - CHAP
A1  - Trukenbrod, Hans Arne
A1  - Barthelme, S.
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Color does not guide eye movements: Evidence from a gaze-contingent
 experiment
T2  - PERCEPTION
Y1  - 2012
SN  - 0301-0066
SN  - 1468-4233
VL  - 41
SP  - 88
EP  - 88
PB  - PION LTD
CY  - LONDON
ER  - 
TY  - THES
A1  - Trukenbrod, Hans Arne
T1  - Temporal and spatial aspects of eye-movement control : from reading to scanning
T1  - Zeitliche und räumliche Aspekte der Blicksteuerung : vom Lesen zum Scannen
N2  - Eye movements are a powerful tool to examine cognitive processes. However, in most paradigms little is known about the dynamics present in sequences of saccades and fixations. In particular, the control of fixation durations has been widely neglected in most tasks. As a notable exception, both spatial and temporal aspects of eye-movement control have been thoroughly investigated during reading. There, the scientific discourse was dominated by three controversies, (i), the role of oculomotor vs. cognitive processing on eye-movement control, (ii) the serial vs. parallel processing of words, and, (iii), the control of fixation durations. The main purpose of this thesis was to investigate eye movements in tasks that require sequences of fixations and saccades. While reading phenomena served as a starting point, we examined eye guidance in non-reading tasks with the aim to identify general principles of eye-movement control. In addition, the investigation of eye movements in non-reading tasks helped refine our knowledge about eye-movement control during reading. Our approach included the investigation of eye movements in non-reading experiments as well as the evaluation and development of computational models. I present three main results : First, oculomotor phenomena during reading can also be observed in non-reading tasks (Chapter 2 & 4). Oculomotor processes determine the fixation position within an object. The fixation position, in turn, modulates both the next saccade target and the current fixation duration. Second, predicitions of eye-movement models based on sequential attention shifts were falsified (Chapter 3). In fact, our results suggest that distributed processing of multiple objects forms the basis of eye-movement control. Third, fixation durations are under asymmetric control (Chapter 4). While increasing processing demands immediately prolong fixation durations, decreasing processing demands reduce fixation durations only with a temporal delay. We propose a computational model ICAT to account for asymmetric control. In this model, an autonomous timer initiates saccades after random time intervals independent of ongoing processing. However, processing demands that are higher than expected inhibit the execution of the next saccade and, thereby, prolong the current fixation. On the other hand, lower processing demands will not affect the duration before the next saccade is executed. Since the autonomous timer adjusts to expected processing demands from fixation to fixation, a decrease in processing demands may lead to a temporally delayed reduction of fixation durations. In an extended version of ICAT, we evaluated its performance while simulating both temporal and spatial aspects of eye-movement control. The eye-movement phenomena investigated in this thesis have now been observed in a number of different tasks, which suggests that they represent general principles of eye guidance. I propose that distributed processing of the visual input forms the basis of eye-movement control, while fixation durations are controlled by the principles outlined in ICAT. In addition, oculomotor control contributes considerably to the variability observed in eye movements. Interpretations for the relation between eye movements and cognition strongly benefit from a precise understanding of this interplay.
N2  - Blickbewegungen stellen ein wichtiges Instrument dar, um kognitive Prozesse zu untersuchen. In den meisten Paradigmen ist allerdings wenig über die Entstehung von Sakkaden und Fixationen bekannt. Insbesondere die Kontrolle der Fixationsdauern wurde häufig außer acht gelassen. Eine wesentliche Ausnahme stellt die Leseforschung dar, in der sowohl zeitlichliche als auch räumliche Aspekte der Blickbewegungssteuerung im Detail betrachtet wurden. Dabei war der wissenschaftliche Diskurs durch drei Kontroversen gekennzeichnet, die untersuchten, (i), welchen Einfluss okulomotorische bzw. kognitive Prozesse auf die Blicksteuerung haben, (ii), ob Worte seriell oder parallel verarbeitet werden und, (iii), wie Fixationsdauern kontrolliert werden. Die vorliegende Arbeit zielt im wesentlichen darauf ab, die Dynamik von Fixationssequenzen zu erforschen. Ausgehend von den Erkenntnissen beim Lesen untersuchten wir Blickbewegungen in Nichtlese-Aufgaben, mit dem Ziel allgemeine Prinzipien der Blicksteuerung zu identifizieren. Zusätzlich versuchten wir mit Hilfe dieser Aufgaben, Erkenntnisse über Prozesse beim Lesen zu vertiefen. Unser Vorgehen war sowohl von der Durchführung von Experimenten als auch der Entwicklung und Evaluation computationaler Modelle geprägt. Die Hauptbefunde zeigten: Erstens, okulomotorische Phänomene des Lesens lassen sich in Suchaufgaben ohne Wortmaterial replizieren (Kapitel 2 & 4). Dabei bestimmen okulomotorische Prozesse die Fixationsposition innerhalb eines Objektes. Diese wiederum beeinflusst das nächste Sakkadenziel sowie die Fixationsdauer. Zweitens, wesentliche Vorhersagen von Modellen, in denen Blickbewegungen von seriellen Aufmerksamkeitsverschiebungen abhängen, konnten falsifiziert werden (Kapitel 3). Stattdessen legen unsere Erkenntnisse nahe, dass die Blicksteuerung von der parallelen Verarbeitung mehrerer Objekte abhängt. Drittens, Fixationsdauern werden asymmetrisch kontrolliert (Kapitel 4). Während hohe Verarbeitungsanforderungen Fixationsdauern unmittelbar verlängern können, führen niedrige Verarbeitungsanforderungen nur zeitlich verzögert zu einer Reduktion. Wir schlagen ein computationales Modell ICAT vor, um asymmetrische Kontrolle zu erklären. Grundlage des Modells ist ein autonomer Zeitgeber, der unabhängig von der momentanen Verarbeitung nach zufälligen Zeitintervallen Sakkaden initiiert. Unerwartet hohe Verarbeitungsanforderungen können die Initiierung der nächsten Sakkade hinauszögern, während unerwartet niedrige Verarbeitungsanforderungen den Beginn der nächsten Sakkade nicht verändern. Der Zeitgeber passt sich allerdings von Fixation zu Fixation neuen Verarbeitungsanforderungen an, so dass es zu einer zeitlich verzögerten Reduktion der Fixationsdauern kommen kann. In einer erweiterten Version des Modells überprüfen wir die Kompatibilität ICATs mit einer realistischen räumlichen Blicksteuerung. Die Ähnlichkeit von Blickbewegungsphänomenen über Aufgaben hinweg legt nahe, dass sie auf allgemeinen Prinzipien basieren. Grundlage der Blicksteuerung ist die verteilte Verarbeitung des visuellen Inputs, während die Kontrolle der Fixationsdauer auf den Prinzipien von ICAT beruht. Darüber hinaus tragen okulomotorische Phänomene wesentlich zur Variabilität der Blicksteuerung bei. Ein Verständnis dieses Zusammenspiels hilft entscheidend den Zusammenhang von Blickbewegungen und Kognitionen besser zu verstehen.
KW  - Blickbewegungen
KW  - Fixationssequenzen
KW  - Computationale Modellierung
KW  - Fixationdauern
KW  - Fixationspositionen
KW  - Eye movements
KW  - fixation sequences
KW  - computational modeling
KW  - fixation durations
KW  - fixation positions
Y1  - 2012
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-70206
ER  - 
TY  - JOUR
A1  - Schütt, Heiko Herbert
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Reich, Sebastian
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Likelihood-based parameter estimation and comparison of dynamical cognitive models
JF  - Psychological Review
N2  - Dynamical models of cognition play an increasingly important role in driving theoretical and experimental research in psychology. Therefore, parameter estimation, model analysis and comparison of dynamical models are of essential importance. In this article, we propose a maximum likelihood approach for model analysis in a fully dynamical framework that includes time-ordered experimental data. Our methods can be applied to dynamical models for the prediction of discrete behavior (e.g., movement onsets); in particular, we use a dynamical model of saccade generation in scene viewing as a case study for our approach. For this model, the likelihood function can be computed directly by numerical simulation, which enables more efficient parameter estimation including Bayesian inference to obtain reliable estimates and corresponding credible intervals. Using hierarchical models inference is even possible for individual observers. Furthermore, our likelihood approach can be used to compare different models. In our example, the dynamical framework is shown to outperform nondynamical statistical models. Additionally, the likelihood based evaluation differentiates model variants, which produced indistinguishable predictions on hitherto used statistics. Our results indicate that the likelihood approach is a promising framework for dynamical cognitive models.
KW  - likelihood
KW  - model fitting
KW  - dynamical model
KW  - eye movements
KW  - model comparison
Y1  - 2017
U6  - https://doi.org/10.1037/rev0000068
SN  - 0033-295X
SN  - 1939-1471
VL  - 124
IS  - 4
SP  - 505
EP  - 524
PB  - American Psychological Association
CY  - Washington
ER  - 
TY  - JOUR
A1  - Schütt, Heiko Herbert
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
A1  - Wichmann, Felix A.
T1  - Disentangling bottom-up versus top-down and low-level versus high-level influences on eye movements over time
JF  - Journal of vision
N2  - Bottom-up and top-down as well as low-level and high-level factors influence where we fixate when viewing natural scenes. However, the importance of each of these factors and how they interact remains a matter of debate. Here, we disentangle these factors by analyzing their influence over time. For this purpose, we develop a saliency model that is based on the internal representation of a recent early spatial vision model to measure the low-level, bottom-up factor. To measure the influence of high-level, bottom-up features, we use a recent deep neural network-based saliency model. To account for top-down influences, we evaluate the models on two large data sets with different tasks: first, a memorization task and, second, a search task. Our results lend support to a separation of visual scene exploration into three phases: the first saccade, an initial guided exploration characterized by a gradual broadening of the fixation density, and a steady state that is reached after roughly 10 fixations. Saccade-target selection during the initial exploration and in the steady state is related to similar areas of interest, which are better predicted when including high-level features. In the search data set, fixation locations are determined predominantly by top-down processes. In contrast, the first fixation follows a different fixation density and contains a strong central fixation bias. Nonetheless, first fixations are guided strongly by image properties, and as early as 200 ms after image onset, fixations are better predicted by high-level information. We conclude that any low-level, bottom-up factors are mainly limited to the generation of the first saccade. All saccades are better explained when high-level features are considered, and later, this high-level, bottom-up control can be overruled by top-down influences.
KW  - saliency
KW  - fixations
KW  - natural scenes
KW  - visual search
KW  - eye movements
Y1  - 2019
U6  - https://doi.org/10.1167/19.3.1
SN  - 1534-7362
VL  - 19
IS  - 3
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - GEN
A1  - Schütt, Heiko Herbert
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
A1  - Wichmann, Felix A.
T1  - Predicting fixation densities over time from early visual processing
T2  - Perception
N2  - Bottom-up saliency is often cited as a factor driving the choice of fixation locations of human observers, based on the (partial) success of saliency models to predict fixation densities in free viewing. However, these observations are only weak evidence for a causal role of bottom-up saliency in natural viewing behaviour. To test bottom-up saliency more directly, we analyse the performance of a number of saliency models---including our own saliency model based on our recently published model of early visual processing (Schütt & Wichmann, 2017, JoV)---as well as the theoretical limits for predictions over time. On free viewing data our model performs better than classical bottom-up saliency models, but worse than the current deep learning based saliency models incorporating higher-level information like knowledge about objects. However, on search data all saliency models perform worse than the optimal image independent prediction. We observe that the fixation density in free viewing is not stationary over time, but changes over the course of a trial. It starts with a pronounced central fixation bias on the first chosen fixation, which is nonetheless influenced by image content. Starting with the 2nd to 3rd fixation, the fixation density is already well predicted by later densities, but more concentrated. From there the fixation distribution broadens until it reaches a stationary distribution around the 10th fixation. Taken together these observations argue against bottom-up saliency as a mechanistic explanation for eye movement control after the initial orienting reaction in the first one to two saccades, although we confirm the predictive value of early visual representations for fixation locations. The fixation distribution is, first, not well described by any stationary density, second, is predicted better when including object information and, third, is badly predicted by any saliency model in a search task.
Y1  - 2019
SN  - 0301-0066
SN  - 1468-4233
VL  - 48
SP  - 64
EP  - 65
PB  - Sage Publ.
CY  - London
ER  - 
TY  - GEN
A1  - Schwetlick, Lisa
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
T1  - The Influence of Visual Long Term Memory on Eye Movements During Scene Viewing
T2  - Perception
Y1  - 2019
SN  - 0301-0066
SN  - 1468-4233
VL  - 48
IS  - S1
SP  - 138
EP  - 138
PB  - Sage Publ.
CY  - London
ER  - 
TY  - JOUR
A1  - Schwetlick, Lisa
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
T1  - Modeling the effects of perisaccadic attention on gaze statistics during scene viewing
JF  - Communications biology
N2  - Lisa Schwetlick et al. present a computational model linking visual scan path generation in scene viewing to physiological and experimental work on perisaccadic covert attention, the act of attending to an object visually without obviously moving the eyes toward it. They find that integrating covert attention into predictive models of visual scan paths greatly improves the model's agreement with experimental data. <br /> How we perceive a visual scene depends critically on the selection of gaze positions. For this selection process, visual attention is known to play a key role in two ways. First, image-features attract visual attention, a fact that is captured well by time-independent fixation models. Second, millisecond-level attentional dynamics around the time of saccade drives our gaze from one position to the next. These two related research areas on attention are typically perceived as separate, both theoretically and experimentally. Here we link the two research areas by demonstrating that perisaccadic attentional dynamics improve predictions on scan path statistics. In a mathematical model, we integrated perisaccadic covert attention with dynamic scan path generation. Our model reproduces saccade amplitude distributions, angular statistics, intersaccadic turning angles, and their impact on fixation durations as well as inter-individual differences using Bayesian inference. Therefore, our result lend support to the relevance of perisaccadic attention to gaze statistics.
KW  - Computational models
KW  - Human behaviour
KW  - Visual system
Y1  - 2020
U6  - https://doi.org/10.1038/s42003-020-01429-8
SN  - 2399-3642
VL  - 3
IS  - 1
PB  - Springer Nature
CY  - London
ER  - 
TY  - JOUR
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Schütt, Heiko Herbert
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Temporal evolution of the central fixation bias in scene viewing
JF  - Journal of vision
N2  - When watching the image of a natural scene on a computer screen, observers initially move their eyes toward the center of the image—a reliable experimental finding termed central fixation bias. This systematic tendency in eye guidance likely masks attentional selection driven by image properties and top-down cognitive processes. Here, we show that the central fixation bias can be reduced by delaying the initial saccade relative to image onset. In four scene-viewing experiments we manipulated observers' initial gaze position and delayed their first saccade by a specific time interval relative to the onset of an image. We analyzed the distance to image center over time and show that the central fixation bias of initial fixations was significantly reduced after delayed saccade onsets. We additionally show that selection of the initial saccade target strongly depended on the first saccade latency. A previously published model of saccade generation was extended with a central activation map on the initial fixation whose influence declined with increasing saccade latency. This extension was sufficient to replicate the central fixation bias from our experiments. Our results suggest that the central fixation bias is generated by default activation as a response to the sudden image onset and that this default activation pattern decreases over time. Thus, it may often be preferable to use a modified version of the scene viewing paradigm that decouples image onset from the start signal for scene exploration to explicitly reduce the central fixation bias.
KW  - eye movements
KW  - dynamic models
KW  - visual scanpath
KW  - visual attention
Y1  - 2017
U6  - https://doi.org/10.1167/17.13.3
SN  - 1534-7362
VL  - 17
SP  - 1626
EP  - 1638
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - JOUR
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
A1  - Schütt, Heiko Herbert
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Influence of initial fixation position in scene viewing
JF  - Vision research : an international journal for functional aspects of vision.
KW  - Visual scanpath
KW  - Visual attention
KW  - Inhibition of return
KW  - Eye movements
KW  - Saliency
Y1  - 2016
U6  - https://doi.org/10.1016/j.visres.2016.09.012
SN  - 0042-6989
SN  - 1878-5646
VL  - 129
SP  - 33
EP  - 49
PB  - Elsevier
CY  - Oxford
ER  - 
TY  - JOUR
A1  - Rothkegel, Lars Oliver Martin
A1  - Schütt, Heiko Herbert
A1  - Trukenbrod, Hans Arne
A1  - Wichmann, Felix A.
A1  - Engbert, Ralf
T1  - Searchers adjust their eye-movement dynamics to target characteristics in natural scenes
JF  - Scientific reports
N2  - When searching a target in a natural scene, it has been shown that both the target’s visual properties and similarity to the background influence whether and how fast humans are able to find it. So far, it was unclear whether searchers adjust the dynamics of their eye movements (e.g., fixation durations, saccade amplitudes) to the target they search for. In our experiment, participants searched natural scenes for six artificial targets with different spatial frequency content throughout eight consecutive sessions. High-spatial frequency targets led to smaller saccade amplitudes and shorter fixation durations than low-spatial frequency targets if target identity was known. If a saccade was programmed in the same direction as the previous saccade, fixation durations and successive saccade amplitudes were not influenced by target type. Visual saliency and empirical fixation density at the endpoints of saccades which maintain direction were comparatively low, indicating that these saccades were less selective. Our results suggest that searchers adjust their eye movement dynamics to the search target efficiently, since previous research has shown that low-spatial frequencies are visible farther into the periphery than high-spatial frequencies. We interpret the saccade direction specificity of our effects as an underlying separation into a default scanning mechanism and a selective, target-dependent mechanism.
Y1  - 2019
U6  - https://doi.org/10.1038/s41598-018-37548-w
SN  - 2045-2322
VL  - 9
PB  - Nature Publ. Group
CY  - London
ER  - 
TY  - JOUR
A1  - Engbert, Ralf
A1  - Trukenbrod, Hans Arne
A1  - Barthelme, Simon
A1  - Wichmann, Felix A.
T1  - Spatial statistics and attentional dynamics in scene viewing
JF  - Journal of vision
N2  - In humans and in foveated animals visual acuity is highly concentrated at the center of gaze, so that choosing where to look next is an important example of online, rapid decision-making. Computational neuroscientists have developed biologically-inspired models of visual attention, termed saliency maps, which successfully predict where people fixate on average. Using point process theory for spatial statistics, we show that scanpaths contain, however, important statistical structure, such as spatial clustering on top of distributions of gaze positions. Here, we develop a dynamical model of saccadic selection that accurately predicts the distribution of gaze positions as well as spatial clustering along individual scanpaths. Our model relies on activation dynamics via spatially-limited (foveated) access to saliency information, and, second, a leaky memory process controlling the re-inspection of target regions. This theoretical framework models a form of context-dependent decision-making, linking neural dynamics of attention to behavioral gaze data.
KW  - scene perception
KW  - eye movements
KW  - attention
KW  - saccades
KW  - modeling
KW  - spatial statistics
Y1  - 2015
U6  - https://doi.org/10.1167/15.1.14
SN  - 1534-7362
VL  - 15
IS  - 1
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - JOUR
A1  - Barthelme, Simon
A1  - Trukenbrod, Hans Arne
A1  - Engbert, Ralf
A1  - Wichmann, Felix A.
T1  - Modeling fixation locations using spatial point processes
JF  - Journal of vision
N2  - Whenever eye movements are measured, a central part of the analysis has to do with where subjects fixate and why they fixated where they fixated. To a first approximation, a set of fixations can be viewed as a set of points in space; this implies that fixations are spatial data and that the analysis of fixation locations can be beneficially thought of as a spatial statistics problem. We argue that thinking of fixation locations as arising from point processes is a very fruitful framework for eye-movement data, helping turn qualitative questions into quantitative ones. We provide a tutorial introduction to some of the main ideas of the field of spatial statistics, focusing especially on spatial Poisson processes. We show how point processes help relate image properties to fixation locations. In particular we show how point processes naturally express the idea that image features' predictability for fixations may vary from one image to another. We review other methods of analysis used in the literature, show how they relate to point process theory, and argue that thinking in terms of point processes substantially extends the range of analyses that can be performed and clarify their interpretation.
KW  - eye movements
KW  - fixation locations
KW  - saliency
KW  - modeling
KW  - point process
KW  - spatial statistics
Y1  - 2013
U6  - https://doi.org/10.1167/13.12.1
SN  - 1534-7362
VL  - 13
IS  - 12
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  - 
TY  - GEN
A1  - Backhaus, Daniel
A1  - Engbert, Ralf
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
T1  - Task-dependence in scene perception: Head unrestrained viewing using mobile eye-tracking
T2  - Zweitveröffentlichungen der Universität Potsdam : Humanwissenschaftliche Reihe
N2  - Real-world scene perception is typically studied in the laboratory using static picture viewing with restrained head position. Consequently, the transfer of results obtained in this paradigm to real-word scenarios has been questioned. The advancement of mobile eye-trackers and the progress in image processing, however, permit a more natural experimental setup that, at the same time, maintains the high experimental control from the standard laboratory setting. We investigated eye movements while participants were standing in front of a projector screen and explored images under four specific task instructions. Eye movements were recorded with a mobile eye-tracking device and raw gaze data were transformed from head-centered into image-centered coordinates. We observed differences between tasks in temporal and spatial eye-movement parameters and found that the bias to fixate images near the center differed between tasks. Our results demonstrate that current mobile eye-tracking technology and a highly controlled design support the study of fine-scaled task dependencies in an experimental setting that permits more natural viewing behavior than the static picture viewing paradigm.
T3  - Zweitveröffentlichungen der Universität Potsdam : Humanwissenschaftliche Reihe - 871 
KW  - scene viewing
KW  - real-world scenarios
KW  - mobile eye-tracking
KW  - task influence
KW  - central fixation bias
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-519124
SN  - 1866-8364
IS  - 5
ER  - 
TY  - JOUR
A1  - Backhaus, Daniel
A1  - Engbert, Ralf
A1  - Rothkegel, Lars Oliver Martin
A1  - Trukenbrod, Hans Arne
T1  - Task-dependence in scene perception: Head unrestrained viewing using mobile eye-tracking
JF  - Journal of vision
N2  - Real-world scene perception is typically studied in the laboratory using static picture viewing with restrained head position. Consequently, the transfer of results obtained in this paradigm to real-word scenarios has been questioned. The advancement of mobile eye-trackers and the progress in image processing, however, permit a more natural experimental setup that, at the same time, maintains the high experimental control from the standard laboratory setting. We investigated eye movements while participants were standing in front of a projector screen and explored images under four specific task instructions. Eye movements were recorded with a mobile eye-tracking device and raw gaze data were transformed from head-centered into image-centered coordinates. We observed differences between tasks in temporal and spatial eye-movement parameters and found that the bias to fixate images near the center differed between tasks. Our results demonstrate that current mobile eye-tracking technology and a highly controlled design support the study of fine-scaled task dependencies in an experimental setting that permits more natural viewing behavior than the static picture viewing paradigm.
KW  - scene viewing
KW  - real-world scenarios
KW  - mobile eye-tracking
KW  - task
KW  - influence
KW  - central fixation bias
Y1  - 2020
U6  - https://doi.org/10.1167/jov.20.5.3
SN  - 1534-7362
VL  - 20
IS  - 5
SP  - 1
EP  - 21
PB  - Association for Research in Vision and Opthalmology
CY  - Rockville
ER  -