The role of global cues in the perceptual grouping of natural shapes

Elder, James H.; Oleskiw, Timothy D.; Fruend, Ingo

doi:10.1167/18.12.14

Cited by 8 publications

(10 citation statements)

References 101 publications

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“…Recently, Elder et al (2018) introduced two innovations in the psychophysical method of Field et al (1993) to address these issues. First, instead of employing simple geometric stimuli such as circles or Ss, they employed fragmented outlines of animal shapes, natural stimuli to which we know the human visual system is acutely tuned (see Section 1).…”

Section: Global Cues For Contour Groupingmentioning

confidence: 99%

“…One limitation of backward-masking and TMS studies is that the transient onset of a strong visual mask or the repeated application of a focused magnetic field may generally disrupt processing and reduce performance on a range of tasks by introducing noise or distracting attention, and thus an observed deficit does not demonstrate that the feedback process is specific to the visual task under study (shape processing, in our case). To address this issue, Drewes et al (2016) developed a novel repetition methodology based on the animal and metamer stimuli of Elder et al (2018). In this method, a fragmented shape stimulus is displayed briefly in random dynamic noise, and the observer's task is to distinguish whether the shape is an animal or a metamer.…”

Section: Psychophysical Evidence: Enhancing Feedbackmentioning

confidence: 99%

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Shape from Contour: Computation and Representation

Elder

2018

Annu. Rev. Vis. Sci.

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The human visual system reliably extracts shape information from complex natural scenes in spite of noise and fragmentation caused by clutter and occlusions. A fast, feedforward sweep through ventral stream involving mechanisms tuned for orientation, curvature, and local Gestalt principles produces partial shape representations sufficient for simpler discriminative tasks. More complete shape representations may involve recurrent processes that integrate local and global cues. While feedforward discriminative deep neural network models currently produce the best predictions of object selectivity in higher areas of the object pathway, a generative model may be required to account for all aspects of shape perception. Research suggests that a successful model will account for our acute sensitivity to four key perceptual dimensions of shape: topology, symmetry, composition, and deformation.

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Section: Global Cues For Contour Groupingmentioning

confidence: 99%

Section: Psychophysical Evidence: Enhancing Feedbackmentioning

confidence: 99%

Shape from Contour: Computation and Representation

Elder

2018

Annu. Rev. Vis. Sci.

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“…Here, we show that standard DCNs struggle to match the superior performance, sample efficiency and generalizability of the proposed recurrent V1Net-1L model on 2 contour integration tasks. On this note we believe that the utility of bio-inspired recurrent models such as V1Net should be explored in overcoming some of the recent deficiencies (where texture is biased over shape) observed in DCNs [21,6,4,45,40] by emphasizing extended contour processing through recurrent horizontal interactions [44,14,15].…”

Section: Discussionmentioning

confidence: 99%

“…V1Net models in our experiments were trained with 5 recurrent iterations. The kernel width of excitatory connections W exc is [15,15], which is thrice the size of our input kernel W xh in order to support far long-range excitatory connections. Inhibitory and divisive gain control connections are implemented by [7,7] separable convolution kernels W inh and W div respectively.…”

Section: Supplementary Information S1 Architecture Details Of Feedfor...mentioning

confidence: 99%

Learning compact generalizable neural representations supporting perceptual grouping

Veerabadran,

de Sa

2020

Preprint

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Work at the intersection of vision science and deep learning is starting to explore the efficacy of deep convolutional networks (DCNs) and recurrent networks in solving perceptual grouping problems that underlie primate visual recognition and segmentation [7,43]. Here, we extend this line of work to investigate the compactness and generalizability of DCN solutions to learning low-level perceptual grouping routines involving contour integration. We introduce V1Net, a bio-inspired recurrent unit that incorporates lateral connections ubiquitous in cortical circuitry. Feedforward convolutional layers in DCNs can be substituted with V1Net modules to enhance their contextual visual processing support for perceptual grouping. We compare the learning efficiency and accuracy of V1Net-DCNs to that of 14 carefully selected feedforward and recurrent neural architectures (including state-of-the-art DCNs) on MarkedLong -a synthetic forced-choice contour integration dataset of 800,000 images we introduce here -and the previously published Pathfinder contour integration benchmarks [43]. We gauged solution generalizability by measuring the transfer learning performance of our candidate models trained on MarkedLong that were fine-tuned to learn PathFinder. Our results demonstrate that a compact 3-layer V1Net-DCN matches or outperforms the test accuracy and sample efficiency of all tested comparison models which contain between 5x and 1000x more trainable parameters; we also note that V1Net-DCN learns the most compact generalizable solution to MarkedLong. A visualization of the temporal dynamics of a V1Net-DCN elucidates its usage of interpretable grouping computations to solve MarkedLong. The compact and rich representations of V1Net-DCN also make it a promising candidate to build on-device machine vision algorithms as well as help better understand biological cortical circuitry.Preprint. Under review.

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“…We used population Monte Carlo (Cappé, Guilin, Marin, & Robert, 2004), starting with 391 circles. At each step of the algorithm, each of the 391 outlines was randomly perturbed using the technique developed by (Fruend & Elder, 2013, see also Elder, Oleskiw, & Fruend, 2018) and the resulting, perturbed outlines were re-sampled based on the fit with the target distribution. This procedure leads to a fair sample from the maximum entropy distribution of closed, non-intersecting shapes that match the marginal turning angle distribution of the animal outlines.…”

Section: Stimulimentioning

confidence: 99%

Radial frequency patterns describe a small and perceptually distinct subset of all possible planar shapes

Schmidtmann

Fruend

2019

Vision Research

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Radial frequency patterns describe a small and perceptually distinct subset of all possible planar shapes.Schmidtmann, GThe visual system is exposed to a vast number of shapes and objects. Yet, human object recognition is effortless, fast and largely independent of naturally occurring transformations such as position and scale. The precise mechanisms of shape encoding are still largely unknown. Radial frequency (RF) patterns are a special class of closed contours defined by modulation of a circle's radius. These patterns have been frequently and successfully used as stimuli in vision science to investigate aspects of shape processing. Given their mathematical properties, RF patterns can not represent any arbitrary shape, but the ability to generate more complex, biologically relevant, shapes depicting the outlines of objects such as fruits or human heads raises the possibility that RF patterns span a representative subset of possible shapes. However, this assumption has not been tested before. Here we show that only a small fraction of all possible shapes can be represented by RF patterns and that this small fraction is perceptually distinct from the general class of all possible shapes. Specifically, we derive a general measure for the distance of a given shape's outline from the set of RF patterns, allowing us to scan large numbers of object outlines automatically. We find that only between 1% and 6% of naturally smooth outlines can be exactly represented by RF patterns. We present results from a visual search experiment, which revealed that searching an RF pattern among non-radial frequency patterns is efficient, whereas searching an RF pattern among other RF patterns is inefficient (and vice versa). These results suggest that RF patterns represent only a restricted subset of possible planar shapes and that results obtained with this special class of stimuli can not simply be expected to generalise to any arbitrary planar shape.

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The role of global cues in the perceptual grouping of natural shapes

Cited by 8 publications

References 101 publications

Shape from Contour: Computation and Representation

Shape from Contour: Computation and Representation

Learning compact generalizable neural representations supporting perceptual grouping

Radial frequency patterns describe a small and perceptually distinct subset of all possible planar shapes

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