Learned feature regularities enable suppression of spatially overlapping stimuli

• Published in: Attention, perception & psychophysics Vol. 85; no. 3; pp. 769 - 784
• Main Authors: Thayer, Daniel D., Miller, Maggie, Giesbrecht, Barry, Sprague, Thomas C.
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.04.2023; Springer Nature B.V
• Subjects: Arrays; Attention - physiology; Behavioral Science and Psychology; Cognitive Psychology; Explicit knowledge; Humans; Influence; Inhibition; Learning; Probability; Psychology; Reaction Time - physiology; Stimuli; Visual Stimuli; Statistical learning; Distractor suppression; Attention
• ISSN: 1943-3921; 1943-393X; 1943-393X
• DOI: 10.3758/s13414-022-02612-1

Contemporary theories of attentional control state that information can be prioritized based on selection history. Even though theories agree that selection history can impact representations of spatial location, which in turn helps guide attention, there remains disagreement on whether nonspatial features (e.g., color) are modulated in a similar way. While previous work has demonstrated color suppression using visual search tasks, it is possible that the location corresponding to the distractor was suppressed, consistent with a spatial mechanism of suppression. Here, we sought to rule out this possibility by testing whether similar suppression of a learned distractor color can occur for spatially overlapping visual stimuli. On a given trial, two spatially superimposed stimuli (line arrays) were tilted either left or right of vertical and presented in one of four distinct colors. Subjects performed a speeded report of the orientation of the “target” array with the most lines. Critically, the distractor array was regularly one color, and this high-probability color was never the color of the target array, which encouraged learned suppression. In two experiments, responses to the target array were fastest when the distractor array was in the high-probability color, suggesting participants suppressed the distractor color. Additionally, when regularities were removed, the high-probability distractor color continued to benefit speeded target identification for individual subjects (E1) but slowed target identification (E2) when presented in the target array. Together, these results indicate that learned suppression of feature-based regularities modulates target detection performance independent of spatial location and persists over time.