More crowded, less numerous: Crowding reduces the number of perceived items in numerosity perception

Humans can estimate the number of visually displayed items without counting. This capacity of numerosity perception has often been attributed to a dedicated system to estimate numerosity, or alternatively to the exploitation of various stimulus features, such as density, convex hull, the size of items and occupancy area. The distribution of the presented items is usually not varied with eccentricity in the visual field. However, our visual fields are highly asymmetric, and to date, it is unclear how inhomogeneities of the visual field impact numerosity perception. Besides eccentricity, a pronounced asymmetry is the radial-tangential anisotropy. For example, in crowding, radially placed flankers interfere more strongly with target perception than tangentially placed flankers. Similarly, in redundancy masking, the number of perceived items in repeating patterns is reduced when the items are arranged radially but not when they are arranged tangentially. Here, we investigated whether numerosity perception is subject to the radial-tangential anisotropy of spatial vision to shed light on the underlying topology of numerosity perception. Observers were presented with varying numbers of discs and asked to report the perceived number. There were two conditions. Discs were predominantly arranged radially in the “radial” condition and tangentially in the “tangential” condition. Additionally, the spacing between discs was scaled with eccentricity. Physical properties, such as average eccentricity, average spacing, convex hull, and density were kept as similar as possible in the two conditions. Radial arrangements were expected to yield underestimation compared to tangential arrangements. Consistent with the hypothesis, numerosity estimates in the radial condition were lower compared to the tangential condition. Magnitudes of radial alignment (as well as predicted crowding strength) correlated with the observed numerosity estimates. Our results demonstrate a robust radial-tangential anisotropy, suggesting that the topology of spatial vision determines numerosity estimation. We suggest that asymmetries of spatial vision should be taken into account when investigating numerosity estimation.

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Looking for more food or more people? Task context influences basic numerosity perception

Cortex ◽

10.1016/j.cortex.2018.05.021 ◽

2019 ◽

Vol 114 ◽

pp. 67-75 ◽

Cited By ~ 3

Author(s):

Michele Fornaciai ◽

Abigail Farrell ◽

Joonkoo Park

Keyword(s):

Task Context ◽

Numerosity Perception

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Subitizing as a case of numerosity perception

10.5353/th_b3120733 ◽

1986 ◽

Author(s):

Siu-ping Lee

Keyword(s):

Numerosity Perception

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Topology-defined units in numerosity perception

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1512408112 ◽

2015 ◽

Vol 112 (41) ◽

pp. E5647-E5655 ◽

Cited By ~ 33

Author(s):

Lixia He ◽

Ke Zhou ◽

Tiangang Zhou ◽

Sheng He ◽

Lin Chen

Keyword(s):

Number Sense ◽

Color Contrast ◽

Intraparietal Sulcus ◽

Tuning Curves ◽

Visual Property ◽

Numerosity Judgment ◽

Wide Range ◽

Color Similarity ◽

Equality Judgment ◽

Numerosity Perception

What is a number? The number sense hypothesis suggests that numerosity is “a primary visual property” like color, contrast, or orientation. However, exactly what attribute of a stimulus is the primary visual property and determines numbers in the number sense? To verify the invariant nature of numerosity perception, we manipulated the numbers of items connected/enclosed in arbitrary and irregular forms while controlling for low-level features (e.g., orientation, color, and size). Subjects performed discrimination, estimation, and equality judgment tasks in a wide range of presentation durations and across small and large numbers. Results consistently show that connecting/enclosing items led to robust numerosity underestimation, with the extent of underestimation increasing monotonically with the number of connected/enclosed items. In contrast, grouping based on color similarity had no effect on numerosity judgment. We propose that numbers or the primitive units counted in numerosity perception are influenced by topological invariants, such as connectivity and the inside/outside relationship. Beyond the behavioral measures, neural tuning curves to numerosity in the intraparietal sulcus were obtained using functional MRI adaptation, and the tuning curves showed that numbers represented in the intraparietal sulcus were strongly influenced by topology.

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Perceiving numerosity from birth

Behavioral and Brain Sciences ◽

10.1017/s0140525x16002090 ◽

2017 ◽

Vol 40 ◽

Cited By ~ 8

Author(s):

Maria Dolores de Hevia ◽

Elisa Castaldi ◽

Arlette Streri ◽

Evelyn Eger ◽

Véronique Izard

Keyword(s):

Convex Hull ◽

Item Size ◽

Numerosity Perception

AbstractLeibovich et al. opened up an important discussion on the nature and origins of numerosity perception. The authors rightly point out that non-numerical features of stimuli influence this ability. Despite these biases, there is evidence that from birth, humans perceive and represent numerosities, and not just non-numerical quantitative features such as item size, density, and convex hull.

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Visual Orientational Anisotropy and Stimulus Surround Effects in Discrimination of Spatial Numerosity

Perceptual and Motor Skills ◽

10.2466/pms.1976.43.2.431 ◽

1976 ◽

Vol 43 (2) ◽

pp. 431-438

Author(s):

Eugene C. Lechelt ◽

Gordon Tanne

Keyword(s):

Spatial Orientation ◽

Stimulus Field ◽

Visual Spatial ◽

Numerosity Perception

Visual spatial numerosity perception was investigated as a function of spatial orientation and surround conditions. 3 to 13 dots arranged linearly in horizontal, vertical, or oblique orientations were presented for 200 msec. in either a square or circular stimulus field. For patterns with small numbers of dots (3 to 7), surround and orientation conditions did not substantially alter perceived number except vertical arrangements were judged as having reliably more dots than identical horizontal arrangements. For large dot-number patterns (8 to 13), surround significantly altered perceived number and left oblique linear arrangements were judged to have reliably more dots than equivalent arrangements in all other orientations.

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Numerosity Comparison, Estimation and Proportion Estimation Abilities May Predict Numeracy and Cognitive Reflection in Adults

Frontiers in Human Neuroscience ◽

10.3389/fnhum.2021.762344 ◽

2021 ◽

Vol 15 ◽

Author(s):

Midori Tokita ◽

Sumire Hirota

Keyword(s):

Cognitive Abilities ◽

Number System ◽

Cognitive Mechanisms ◽

Cognitive Reflection Test ◽

Comparison Task ◽

Cognitive Reflection ◽

Japanese Adults ◽

Proportion Estimation ◽

Numerosity Estimation ◽

Numerosity Perception

This study explores whether and how different tasks associated with approximate number system (ANS) ability are related to numeracy and cognitive reflection in adults. We conducted an online experiment using a sample of 300 Japanese adults aged 20–39. Participants were given three ANS tasks (numerosity comparison, numerosity estimation, and proportion estimation) as well as Rasch-based numeracy scale and cognitive reflection test, and we tested the correlation among the measures of these tasks. We explored the hypothesis that the typical measures used to gauge ANS ability, numerosity comparison and numerosity estimation may mediate different cognitive mechanisms in adults. We also introduced a task measuring proportion estimation, added because such estimation requires numerosity perception and the ability to map symbolic numerals. Our findings suggest that there is a weak, but significant correlation among the three ANS-related tasks. Moreover, there is a significant relationship between each of these measures and the numeracy and CRT score, suggesting that the ANS-related ability may be associated with higher cognitive abilities such as numeracy and cognitive reflection. In addition, we found that performances on the numerosity and proportion estimation are more clearly related to CRT score than the numerosity comparison task.

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Mapping numerical perception and operations in relation to functional and anatomical landmarks of human parietal cortex

10.1101/602599 ◽

2019 ◽

Cited By ~ 1

Author(s):

Elisa Castaldi ◽

Alexandre Vignaud ◽

Evelyn Eger

Keyword(s):

Middle Part ◽

Anatomical Landmarks ◽

Functional Neuroanatomy ◽

Different Types ◽

Functional Equivalent ◽

Human Adults ◽

Ventral Intraparietal Area ◽

Numerosity Perception ◽

7T Fmri ◽

Numerical Operations

AbstractHuman functional imaging has identified the middle part of the intraparietal sulcus (IPS) as an important brain substrate for different types of numerical tasks. This area is often equated with the macaque ventral intraparietal area (VIP) where neuronal selectivity for non-symbolic numbers is found. However, the low spatial resolution and whole-brain averaging analysis performed in most fMRI studies limit the extent to which an exact correspondence of activation in different numerical tasks with specific sub-regions of the IPS can be established. Here we disentangled the functional neuroanatomy of numerical perception and operations (comparison and calculation) by acquiring high-resolution 7T fMRI data in a group of human adults, and relating the activations in different numerical contrasts to anatomical and functional landmarks on the cortical surface. Our results reveal a functional heterogeneity within human intraparietal cortex where the visual field map representations in superior/medial parts of IPS and superior parietal gyrus are involved predominantly in numerosity perception, whereas numerical operations predominantly recruit lateral/inferior parts of IPS. Since calculation and comparison-related activity fell mainly outside the field map representations considered the functional equivalent of the monkey VIP/LIP complex, the areas most activated during such numerical operations in humans are likely different from VIP.

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Resources Underlying Visuo-Spatial Working Memory Enable Veridical Large Numerosity Perception

Frontiers in Human Neuroscience ◽

10.3389/fnhum.2021.751098 ◽

2021 ◽

Vol 15 ◽

Author(s):

Elisa Castaldi ◽

Manuela Piazza ◽

Evelyn Eger

Keyword(s):

Working Memory ◽

Spatial Working Memory ◽

Memory Task ◽

Visual Image ◽

Verbal Working Memory ◽

Clinical Population ◽

Cognitive Resources ◽

Multiple Objects ◽

Numerosity Discrimination ◽

Numerosity Perception

Humans can quickly approximate how many objects are in a visual image, but no clear consensus has been achieved on the cognitive resources underlying this ability. Previous work has lent support to the notion that mechanisms which explicitly represent the locations of multiple objects in the visual scene within a mental map are critical for both visuo-spatial working memory and enumeration (at least for relatively small numbers of items). Regarding the cognitive underpinnings of large numerosity perception, an issue currently subject to much controversy is why numerosity estimates are often non-veridical (i.e., susceptible to biases from non-numerical quantities). Such biases have been found to be particularly pronounced in individuals with developmental dyscalculia (DD), a learning disability affecting the acquisition of arithmetic skills. Motivated by findings showing that DD individuals are also often impaired in visuo-spatial working memory, we hypothesized that resources supporting this type of working memory, which allow for the simultaneous identification of multiple objects, might also be critical for precise and unbiased perception of larger numerosities. We therefore tested whether loading working memory of healthy adult participants during discrimination of large numerosities would lead to increased interference from non-numerical quantities. Participants performed a numerosity discrimination task on multi-item arrays in which numerical and non-numerical stimulus dimensions varied congruently or incongruently relative to each other, either in isolation or in the context of a concurrent visuo-spatial or verbal working memory task. During performance of the visuo-spatial, but not verbal, working memory task, precision in numerosity discrimination decreased, participants’ choices became strongly biased by item size, and the strength of this bias correlated with measures of arithmetical skills. Moreover, the interference between numerosity and working memory tasks was bidirectional, with number discrimination impacting visuo-spatial (but not verbal) performance. Overall, these results suggest that representing visual numerosity in a way that is unbiased by non-numerical quantities relies on processes which explicitly segregate/identify the locations of multiple objects that are shared with visuo-spatial (but not verbal) working memory. This shared resource may potentially be impaired in DD, explaining the observed co-occurrence of working memory and numerosity discrimination deficits in this clinical population.

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