Distractor suppression leads to reduced flanker interference

Ivanov, Yavor; Theeuwes, Jan

doi:10.3758/s13414-020-02159-z

Cited by 11 publications

(15 citation statements)

References 60 publications

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“…Experiment 1 was conducted using an online platform ( Pavlovia.org ) during a period when in-person testing was halted due to COVID-19. The online platform was validated by a recent publication that revealed LPL in online testing (Ivanov & Theeuwes, 2021 ). In addition, we conducted a pilot experiment to validate online testing.…”

Section: Methodsmentioning

confidence: 99%

Independence of implicitly guided attention from goal-driven oculomotor control

Chen

Lee

2022

Atten Percept Psychophys

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Location probability learning—the acquisition of an attentional bias toward locations that frequently contained a search target—shows many characteristics of a search habit. To what degree does it depend on oculomotor control, as might be expected if habit-like attention is grounded in eye movements? Here, we examined the impact of a spatially incompatible oculomotor signal on location probability learning (LPL). On each trial of a visual search task, participants first saccaded toward a unique C-shape, whose orientation determined whether participants should continue searching for a T target among L distractors. The C-shape often appeared in one, “C-rich” quadrant that differed from where the T was frequently located. Experiment 1 showed that participants acquired LPL toward the high-probability, “T-rich” quadrant, an effect that persisted in an unbiased testing phase. Participants were also faster finding the target in the vicinity of the C-shape, but this effect did not persist after the C-shape was removed. Experiment 2 found that the C-shape affected search only when it was task-relevant. Experiment 3 replicated and extended the findings of Experiment 1 using eye tracking. Thus, location probability learning is robust in the face of a spatially incompatible saccade, demonstrating partial independence between experience-guided attention and goal-driven oculomotor control. The findings are in line with the modular view of attention, which conceptualizes the search habit as a high-level process abstracted from eye movements.

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Section: Methodsmentioning

confidence: 99%

Independence of implicitly guided attention from goal-driven oculomotor control

Chen

Lee

2022

Atten Percept Psychophys

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“…These findings indicate that the high-probability location was suppressed relative to the other display locations, attenuating the salience signal of stimuli presented at that location (Ferrante et al, 2018;Ivanov & Theeuwes, 2021;Wang & Theeuwes, 2018b, 2018a. Presumably, the weights within the spatial priority map, based on which attention is deployed, were adjusted so that the high-probability location was assigned a low priority to prevent distractor capture (Ferrante et al, 2018;Ivanov & Theeuwes, 2021;Wang & Theeuwes, 2018a, 2018b. Further research demonstrated that distractor location learning is modulated not only by learning of spatial, but also of nonspatial distractor regularities (Failing et al, 2019;van Moorselaar et al, 2020).…”

Section: Introductionmentioning

confidence: 92%

“…Second, when the target was presented at the high-probability location of the distractor, target selection was impaired (but see Allenmark et al, 2019;van Moorselaar et al, 2021). These findings indicate that the high-probability location was suppressed relative to the other display locations, attenuating the salience signal of stimuli presented at that location (Ferrante et al, 2018;Ivanov & Theeuwes, 2021;Wang & Theeuwes, 2018b, 2018a. Presumably, the weights within the spatial priority map, based on which attention is deployed, were adjusted so that the high-probability location was assigned a low priority to prevent distractor capture (Ferrante et al, 2018;Ivanov & Theeuwes, 2021;Wang & Theeuwes, 2018a, 2018b.…”

Section: Introductionmentioning

confidence: 99%

“…Only a few studies have examined the effects of the target template (i.e., search for a feature-specific target vs. shape singleton) on distractor location learning (Ivanov & Theeuwes, 2021;Wang & Theeuwes, 2018c). Wang and Theeuwes (2018) hypothesized that in feature search mode (Bacon & Egeth, 1994), distractors can be ignored by top-down processes, eliminating the need for distractor location learning.…”

Section: Introductionmentioning

confidence: 99%

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Target templates and the time course of distractor location learning

Hanne¹,

Tünnermann²,

Schubö³

2022

Preprint

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When searching for a shape target, colour distractors typically capture our attention. This capture is smaller when observers search for a fixed target that allows for a feature-specific target template compared to a varying shape singleton target. Capture is also reduced when observers can learn to predict the likely distractor location. We investigated how the precision of the target template modulates distractor location learning in an additional singleton search task. As observers are less prone to capture with a feature-specific target, we assumed that distractor location learning is less beneficial and therefore less pronounced than with a singleton target. Hierarchical Bayesian parameter estimation was used to fit fine-grained distractor location learning curves. As expected, distractor cost was reduced for distractors presented at the high-probability location. A model-based analysis of the time course of distractor location learning revealed an effect on the asymptotic performance level: when searching for a feature target, distractor cost was smaller than with a singleton target when distractors were presented at the low-probability locations, but higher at the high-probability location, indicating reduced capture and reduced distractor location learning. These findings suggest that the target template affects distractor handling by down-weighting distractor features, and by modulating how well distractors can be ignored when they appear at predictable, learned locations.

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“…In addition, trial frequencies have often been varied across conditions to explore a variety of cognitive processes by investigating their interactions with probability (e.g., Broadbent & Gregory, 1965;Den Heyer, Briand, & Dannenbring, 1983;Miller & Pachella, 1973;Sanders, 1970;Theios, Smith, Haviland, Traupmann, & Moy, 1973). Currently, trial frequencies are commonly varied in studies of spatial and temporal statistical learning (e.g., Flowers, Palitsky, Sullivan, & Peterson, 2021;Gibson, Pauszek, Trost, & Wenger, 2021;Liesefeld & Müller, 2021;Vadillo, Giménez-Fernández, Beesley, Shanks, & Luque, 2021), the modulation of attentional control processes by environmental contingencies (e.g., Cochrane, Simmering, & Green, 2021;Huang, Theeuwes, & Donk, 2021;Kang & Chiu, 2021), action-outcome contingency learning (e.g., Gao & Gozli, 2021), adaptation to the frequency of congruent versus incongruent information (e.g., Bausenhart, Ulrich, & Miller, 2021;Ivanov & Theeuwes, 2021;Thomson, Simone, & Watter, 2021), and between-task resource sharing (e.g., Miller & Tang, 2021), to name just a few areas. Unfortunately, median bias is still sometimes overlooked and may contaminate published comparisons of conditions with different POWER OF MEDIAN RTS 8 trial frequencies (e.g., Bulger, Shinn-Cunningham, & Noyce, 2021).…”

Section: Type I Error Ratesmentioning

confidence: 99%

Another Warning about Median Reaction Time --- Version of 19 Jan 2022

Miller¹

2020

Preprint

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Contrary to the warning of Miller (1988), Rousselet and Wilcox (2020) argued that it is better to summarize each participant’s single-trial reaction times (RTs) in a given condition with the median than with the mean when comparing the central tendencies of RT distributions across experimental conditions. They acknowledged that median RTs can produce inflated Type I error rates when conditions differ in the number of trials tested, consistent with Miller’s warning, but they showed that the bias responsible for this error rate inflation could be eliminated with a bootstrap bias correction technique. The present simulations extend their analysis by examining the power of bias-corrected medians to detect true experimental effects and by comparing this power with the power of analyses using means and regular medians. Unfortunately, although bias-corrected medians solve the problem of inflated Type I error rates, their power is lower than that of means or regular medians in many realistic situations. In addition, even when conditions do not differ in the number of trials tested, the power of tests (e.g., t-tests) is generally lower using medians rather than means as the summary measures. Thus, the present simulations demonstrate that summary means will often provide the most powerful test for differences between conditions, and they show what aspects of the RT distributions determine the size of the power advantage for means.

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Distractor suppression leads to reduced flanker interference

Cited by 11 publications

References 60 publications

Independence of implicitly guided attention from goal-driven oculomotor control

Independence of implicitly guided attention from goal-driven oculomotor control

Target templates and the time course of distractor location learning

Another Warning about Median Reaction Time --- Version of 19 Jan 2022

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