Publication
] Hierarchically Local Tasks and Deep Convolutional Networks. (2020).
CBMM_Memo_109.pdf (2.12 MB)
CBMM_Memo_109.pdf (2.12 MB) Group Invariant Deep Representations for Image Instance Retrieval. (2016). CBMM-Memo-043.pdf (2.66 MB)
CBMM-Memo-043.pdf (2.66 MB) On Generalization Bounds for Neural Networks with Low Rank Layers. (2024). CBMM-Memo-151.pdf (697.31 KB)
CBMM-Memo-151.pdf (697.31 KB) Function approximation by deep networks. Communications on Pure & Applied Analysis 19, 4085 - 4095 (2020). 1534-0392_2020_8_4085.pdf (514.57 KB)
1534-0392_2020_8_4085.pdf (514.57 KB) From Marr’s Vision to the Problem of Human Intelligence. (2021). CBMM-Memo-118.pdf (362.19 KB)
CBMM-Memo-118.pdf (362.19 KB) From Associative Memories to Powerful Machines. (2021). v1.0 (1.01 MB) v1.3Section added August 6 on self attention (3.9 MB)
v1.0 (1.01 MB) v1.3Section added August 6 on self attention (3.9 MB) Foveation-based Mechanisms Alleviate Adversarial Examples. (2016). cbmm_memo_044.pdf (11.48 MB)
cbmm_memo_044.pdf (11.48 MB) Formation of Representations in Neural Networks. (2024). CBMM-Memo-150.pdf (4.03 MB)
CBMM-Memo-150.pdf (4.03 MB) For interpolating kernel machines, the minimum norm ERM solution is the most stable. (2020). CBMM_Memo_108.pdf (1015.14 KB) Better bound (without inequalities!) (1.03 MB)
CBMM_Memo_108.pdf (1015.14 KB) Better bound (without inequalities!) (1.03 MB) For interpolating kernel machines, minimizing the norm of the ERM solution maximizes stability. Analysis and Applications 21, 193 - 215 (2023).
For HyperBFs AGOP is a greedy approximation to gradient descent. (2024). CBMM-Memo-148.pdf (1.06 MB)
CBMM-Memo-148.pdf (1.06 MB) Fisher-Rao Metric, Geometry, and Complexity of Neural Networks. arXiv.org (2017). at <https://arxiv.org/abs/1711.01530> 1711.01530.pdf (966.99 KB)
1711.01530.pdf (966.99 KB) Feature learning in deep classifiers through Intermediate Neural Collapse. (2023). Feature_Learning_memo.pdf (2.16 MB)
Feature_Learning_memo.pdf (2.16 MB) A fast, invariant representation for human action in the visual system. Journal of Neurophysiology (2018). doi:https://doi.org/10.1152/jn.00642.2017
A fast, invariant representation for human action in the visual system. J Neurophysiol jn.00642.2017 (2017). doi:10.1152/jn.00642.2017 Author's last draft (695.63 KB)
Author's last draft (695.63 KB) Explicit regularization and implicit bias in deep network classifiers trained with the square loss. arXiv (2020). at <https://arxiv.org/abs/2101.00072>
Evaluating the Adversarial Robustness of a Foveated Texture Transform Module in a CNN. NeurIPS 2021 (2021). at <https://nips.cc/Conferences/2021/Schedule?showEvent=21868>
The Effects of Image Distribution and Task on Adversarial Robustness. (2021). CBMM_Memo_116.pdf (5.44 MB)
CBMM_Memo_116.pdf (5.44 MB) Eccentricity Dependent Neural Network with Recurrent Attention for Scale, Translation and Clutter Invariance . Vision Science Society (2019).
Eccentricity Dependent Deep Neural Networks: Modeling Invariance in Human Vision. AAAI Spring Symposium Series, Science of Intelligence (2017). at <https://www.aaai.org/ocs/index.php/SSS/SSS17/paper/view/15360> paper.pdf (963.87 KB)
paper.pdf (963.87 KB) Eccentricity Dependent Deep Neural Networks for Modeling Human Vision. Vision Sciences Society (2017).
The dynamics of invariant object recognition in the human visual system. (2014). doi:http://dx.doi.org/10.7910/DVN/KRUPXZ
The dynamics of invariant object recognition in the human visual system. J Neurophysiol 111, 91-102 (2014).
Dynamics in Deep Classifiers trained with the Square Loss: normalization, low rank, neural collapse and generalization bounds. Research (2023). doi:10.34133/research.0024 research.0024.pdf (4.05 MB)
research.0024.pdf (4.05 MB)