Training for object recognition with increasing spatial frequency: A comparison of deep learning with human vision

Avberšek, Lev Kiar; Zeman, Astrid; Beeck, Hans Op de

doi:10.1167/jov.21.10.14

Cited by 29 publications

(15 citation statements)

References 38 publications

(80 reference statements)

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“…Under this view, we hypothesize that the underdeveloped state of the newborn human visual is functional and, among other things, facilitates the infant’s rapid acquisition of basic-level categories. The work we present here, along with several related studies (French et al, 2002; Vogelsang et al, 2018; Avberšek et al, 2021; Jang & Tong, 2021), supports this hypothesis, suggesting that poor infant vision – in the form of low contrast sensitivity – confers multiple adaptive benefits to the visual learner.…”

Section: Discussionsupporting

confidence: 84%

“…Early experience with blurry images may also improve the robustness of visual recognition across image degradation. This is supported by a recent study by Avberšek et al (2021), who used a coarse-to-fine image training regimen with multiple CNN models. More specifically, they attempted to mirror the trajectory of improving contrast sensitivity over early human development by initially training their models only with lower spatial frequency filtered images and then gradually introducing higher spatial frequencies as training progressed.…”

Section: Introductionsupporting

confidence: 53%

“…Finally, several recent studies have also investigated how training with blurred images impacts learning in neural network models Avberšek et al (2021). investigated the effects of training a neural network on various regimens of progressively blurry-to-clear images.…”

mentioning

confidence: 99%

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Why is human vision so poor in early development? The impact of initial sensitivity to low spatial frequencies on visual category learning

Jinsi

Henderson

Tarr

2022

Preprint

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Humans are born with very low contrast sensitivity, meaning that developing infants experience the world "in a blur". Is this solely a byproduct of maturational processes or is there some functional advantage for beginning life with poor vision? We explore whether reduced visual acuity as a consequence of low contrast sensitivity facilitates the acquisition of basic-level visual categories and, if so, whether this advantage also enhances subordinate-level category learning as visual acuity improves. Using convolutional neural networks (CNNs) and the ecoset dataset to simulate basic-level category learning, we manipulated model training curricula along three dimensions: presence of blurred inputs early in training, rate of blur removal over time, and grayscale versus color inputs. We found that a training regimen where blur starts high and is gradually reduced over time - as in human development - improves basic-level categorization performance relative to a regimen in which non-blurred inputs are used throughout. However, this pattern was observed only when grayscale images were used (analogous to the low sensitivity to color infants experience during early development). Importantly, the observed improvements in basic-level performance generalized to subordinate-level categorization as well: when models were fine-tuned on a dataset including subordinate-level categories (ImageNet), we found that models initially trained with blurred inputs showed a greater performance benefit than models trained solely on non-blurred inputs. Consistent with several other recent studies, we conclude that poor visual acuity in human newborns confers multiple advantages, including, as demonstrated here, more rapid and accurate acquisition of visual object categories at multiple hierarchical levels.

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Section: Discussionsupporting

confidence: 84%

Section: Introductionsupporting

confidence: 53%

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Why is human vision so poor in early development? The impact of initial sensitivity to low spatial frequencies on visual category learning

Jinsi

Henderson

Tarr

2022

Preprint

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“…face classification) [Jang and Tong, 2021]. A recent study using object recognition [Avberšek et al, 2021] reports the effect of training schedule consistent with ours. The task difference may be related to the fact that the optimal discriminative features for object recognition are biased toward high frequencies while only low-frequency features are sufficient for good face classification accuracy [Jang and Tong, 2021].…”

Section: Summary and Discussion Of Sectionsupporting

confidence: 76%

“…It has been suggested that the experience of blurred visual images might be functionally beneficial, enabling the visual system to use global configural structures in image recognition [Grand et al, 2001, Le Grand et al, 2004, Vogelsang et al, 2018. Several recent studies use machine learning of artificial neural networks to computationally test this hypothesis [Vogelsang et al, 2018, Katzhendler and Weinshall, 2019, Avberšek et al, 2021, Jang and Tong, 2021. Vogelsang trained the convolutional network (CNN) to recognize human faces.…”

Section: Introductionmentioning

confidence: 99%

Do training with blurred images make convolutional neural networks closer to humans concerning object recognition performance and internal representations?

Yoshihara

Fukiage

Nishida

2022

Preprint

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It is suggested that experiences of perceiving blurry images in addition to sharp images contribute to the development of robust human visual processing. To computationally investigate the effect of exposure to blurry images, we trained Convolutional Neural Networks (CNNs) on ImageNet object recognition with a variety of combinations of sharp and blurry images. In agreement with related studies, mixed training on sharp and blurred images (B+S) makes the CNNs close to humans with respect to robust object recognition against a change in image blur. B+S training also reduces the texture bias of CNN in recognition of shape-texture-cue-conflict images, but the effect is not strong enough to achieve a strong shape bias comparable to what humans show. Other tests also suggest that B+S training is not sufficient to produce robust human-like object recognition based on global configurational features. We also show using representational similarity analysis and zero-shot transfer learning that B+S-Net does not acquire blur-robust object recognition through separate specialized sub-networks, each for sharp and blurry images, but through a single network analyzing common image features. However, blur training alone does not automatically create a mechanism like the human brain where subband information is integrated into a common representation. Our analyses suggest that experience with blurred images helps the human brain develop neural networks that robustly recognize the surrounding world, but it is not powerful enough to fill a large gap between humans and CNNs.

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Human face and gaze perception is highly context specific and involves bottom-up and top-down neural processing

Hadders‐Algra

2022

Neuroscience & Biobehavioral Reviews

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Training for object recognition with increasing spatial frequency: A comparison of deep learning with human vision

Cited by 29 publications

References 38 publications

Why is human vision so poor in early development? The impact of initial sensitivity to low spatial frequencies on visual category learning

Why is human vision so poor in early development? The impact of initial sensitivity to low spatial frequencies on visual category learning

Do training with blurred images make convolutional neural networks closer to humans concerning object recognition performance and internal representations?

Human face and gaze perception is highly context specific and involves bottom-up and top-down neural processing

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