Summary statistics of size: Fixed processing capacity for multiple ensembles but unlimited processing capacity for single ensembles.

Attarha, Mouna; Moore, Cathleen M.; Vecera, Shaun P.

doi:10.1037/a0036206

Cited by 47 publications

(55 citation statements)

References 63 publications

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“…This finding is consistent with earlier studies claiming that an ensemble takes up approximately the same amount of space in working memory as an individual object [91–93]. In addition, observers are more accurate at processing multiple ensembles when they are presented sequentially, rather than simultaneously [94,95], suggesting that ensembles compete for limited cognitive resources. Finally, the precision of ensemble representations varies as a function of the allocation of attention (i.e., focused versus distribute) [96].…”

Section: Do Observers Have Access To All Of This Information?supporting

confidence: 90%

What is the Bandwidth of Perceptual Experience?

Cohen

Dennett

Kanwisher

2016

Trends in Cognitive Sciences

312

288

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Although our subjective impression is of a richly detailed visual world, numerous empirical results suggest that the amount of visual information observers can perceive and remember at any given moment is limited. How can our subjective impressions be reconciled with these objective observations? Here, we answer this question by arguing that, although we see more than the handful of objects, claimed by prominent models of visual attention and working memory, we still see far less than we think we do. Taken together, we argue that these considerations resolve the apparent conflict between our subjective impressions and empirical data on visual capacity, while also illuminating the nature of the representations underlying perceptual experience.

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Section: Do Observers Have Access To All Of This Information?supporting

confidence: 90%

What is the Bandwidth of Perceptual Experience?

Cohen

Dennett

Kanwisher

2016

Trends in Cognitive Sciences

312

288

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“…Because the distractor is always more similar to one of the two element colors than the mean color is to either one individually, it may be that the distractor is erroneously chosen due to a bias toward the individual representations of the ensembles hues rather than the ensemble mean. The fact that this effect disappears when there are intermediate hues also present (i.e., in the 20-JND, four-color condition) could be taken to suggest that individual representations no longer bias the choice, perhaps due to the constraints of visual working memory inhibiting the encoding of individual items (e.g., Alvarez & Oliva, 2008;Attarha, Moore, & Vecera, 2014;Baijal et al, 2013;Chong & Treisman, 2005a;Corbett & Oriet, 2011;De Fockert & Marchant, 2008). When the hue range is even greater (i.e., 28 JNDs, two colors), we suggest that the difference between distractor and element hues is sufficiently large that similarity to element colors is not strong enough to bias responses toward either option of the 2AFC, so mean accuracy is near chance.…”

Section: Below-chance Performancementioning

confidence: 99%

Effects of ensemble complexity and perceptual similarity on rapid averaging of hue

Maule

Franklin

2015

Journal of Vision

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The ability to extract the mean of features from a rapidly viewed, heterogeneous array of objects has been demonstrated for a number of different visual properties. Few studies have previously investigated the rapid averaging of color; those that did had insufficient stimulus control or inappropriate methods. This study reports three experiments that directly test observers' ability to extract the mean hue from a rapidly presented, multielement color ensemble. In Experiment 1, ensembles varied in number of elements and number of colors. It was found that averaging was harder for ensembles with more colors but that changing the number of elements had no effect on accuracy, supportive of a distributed-attention account of rapid color averaging. Experiment 2a manipulated the hue range present in any single ensemble (varying the perceptual difference between ensemble elements) while still varying the number of colors. Range had a strong effect on ability to pick the mean hue. Experiment 2b found no effect of color categories on the accuracy or speed of mean selection. The results indicate that perceptual difference of elements is the dominant factor affecting ability to average rapidly seen color ensembles. Findings are discussed both in the context of perception and memory of multiple colors and ensemble perception generally.

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“…Evidence for the existence of specialized mechanisms comes from the absence of a set size effect (i.e., ensemble representation precision is fairly constant regardless of the number of items in the set; Attarha, Moore, & Vecera, 2014;Chong & Treisman, 2003Haber man & Whitney, 2009), the speed at which ensembles may be derived (as low as 50 ms), and the availability of ensemble information even when individual item information is unavailable (i.e., as undercrowded conditions or change blindness paradigms; Fischer & Whitney, 2011;Haberman & Whitney, 2011;Parkes et al, 2001). Although there is some suggestion that ensemble rep resentation of size could potentially be explained by sampling just one or two items from an entire array (i.e., not a specialized ensemble mechanism; Myczek & Simons, 2008), there is substan tial evidence showing that many ensemble types are processed in a manner akin to textures (Balas, Nakano, & Rosenholtz, 2009), even when individual item information cannot be resolved (Fischer & Whitney, 2011;Haberman & Whitney, 2011) and therefore cannot be individually sampled.…”

mentioning

confidence: 99%

Individual differences in ensemble perception reveal multiple, independent levels of ensemble representation.

Haberman¹,

Brady²,

Alvarez³

2015

Journal of Experimental Psychology: General

135

209

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Ensemble perception, including the ability to "see the average" from a group of items, operates in numerous feature domains (size, orientation, speed, facial expression, etc.). Although the ubiquity of ensemble representations is well established, the large-scale cognitive architecture of this process remains poorly defined. We address this using an individual differences approach. In a series of experiments, observers saw groups of objects and reported either a single item from the group or the average of the entire group. High-level ensemble representations (e.g., average facial expression) showed complete independence from low-level ensemble representations (e.g., average orientation). In contrast, low-level ensemble representations (e.g., orientation and color) were correlated with each other, but not with high-level ensemble representations (e.g., facial expression and person identity). These results suggest that there is not a single domain-general ensemble mechanism, and that the relationship among various ensemble representations depends on how proximal they are in representational space.

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Summary statistics of size: Fixed processing capacity for multiple ensembles but unlimited processing capacity for single ensembles.

Cited by 47 publications

References 63 publications

What is the Bandwidth of Perceptual Experience?

What is the Bandwidth of Perceptual Experience?

Effects of ensemble complexity and perceptual similarity on rapid averaging of hue

Individual differences in ensemble perception reveal multiple, independent levels of ensemble representation.

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