In typical perceptual learning experiments, one stimulus type (e.g., a bisection stimulus offset either to the left or right) is presented per trial. In roving, two different stimulus types (e.g., a 30′ and a 20′ wide bisection stimulus) are randomly interleaved from trial to trial. Roving can impair both perceptual learning and task sensitivity. Here, we investigate the relationship between the two. Using a bisection task, we found no effect of roving before training. We next trained subjects and they improved. A roving condition applied after training impaired sensitivity
<p>Left panel: in tasks with non-roving stimuli, as in Chen et al. <a href="http://www.plosone.org/a...
<p>(A) Fraction of incorrect network decisions for the combined training with two stimulus widths ( ...
AbstractPerceptual learning improves perception through training. Perceptual learning improves with ...
In typical perceptual learning experiments, one stimulus type (e.g., a bisection stimulus offset eit...
AbstractIn typical perceptual learning experiments, one stimulus type (e.g., a bisection stimulus of...
Training with one type of a visual stimulus usually improves performance. When observers train with ...
AbstractIn perceptual learning, performance usually improves when observers train with one type of s...
AbstractPresenting stimuli of two or more stimulus types randomly interleaved, so called roving, dis...
Perceptual learning improves perception through training. Perceptual learning improves with most sti...
In perceptual learning, performance often improves within a short time if only one stimulus variant ...
Presenting two or more stimulus types randomly interleaved, so-called roving stimuli, disrupts perce...
‘Stimulus roving ’ refers to a paradigm in which the properties of the stimuli to be discriminated v...
<div><p>‘Stimulus roving’ refers to a paradigm in which the properties of the stimuli to be discrimi...
<div><p>(A) Stimulus roving immediately after completion of temporal-patterned training. The left pa...
<div><p>(A) Post- versus pre-training contrast thresholds for four roving contrasts with longer stim...
<p>Left panel: in tasks with non-roving stimuli, as in Chen et al. <a href="http://www.plosone.org/a...
<p>(A) Fraction of incorrect network decisions for the combined training with two stimulus widths ( ...
AbstractPerceptual learning improves perception through training. Perceptual learning improves with ...
In typical perceptual learning experiments, one stimulus type (e.g., a bisection stimulus offset eit...
AbstractIn typical perceptual learning experiments, one stimulus type (e.g., a bisection stimulus of...
Training with one type of a visual stimulus usually improves performance. When observers train with ...
AbstractIn perceptual learning, performance usually improves when observers train with one type of s...
AbstractPresenting stimuli of two or more stimulus types randomly interleaved, so called roving, dis...
Perceptual learning improves perception through training. Perceptual learning improves with most sti...
In perceptual learning, performance often improves within a short time if only one stimulus variant ...
Presenting two or more stimulus types randomly interleaved, so-called roving stimuli, disrupts perce...
‘Stimulus roving ’ refers to a paradigm in which the properties of the stimuli to be discriminated v...
<div><p>‘Stimulus roving’ refers to a paradigm in which the properties of the stimuli to be discrimi...
<div><p>(A) Stimulus roving immediately after completion of temporal-patterned training. The left pa...
<div><p>(A) Post- versus pre-training contrast thresholds for four roving contrasts with longer stim...
<p>Left panel: in tasks with non-roving stimuli, as in Chen et al. <a href="http://www.plosone.org/a...
<p>(A) Fraction of incorrect network decisions for the combined training with two stimulus widths ( ...
AbstractPerceptual learning improves perception through training. Perceptual learning improves with ...