Publication
] Invariant recognition drives neural representations of action sequences. PLOS Computational Biology 13, e1005859 (2017).
journal.pcbi_.1005859.pdf (9.24 MB)
journal.pcbi_.1005859.pdf (9.24 MB) Representation Learning from Orbit Sets for One-shot Classification. AAAI Spring Symposium Series, Science of Intelligence (2017). at <https://www.aaai.org/ocs/index.php/SSS/SSS17/paper/view/15357>
Discriminate-and-Rectify Encoders: Learning from Image Transformation Sets. (2017). CBMM-Memo-062.pdf (9.37 MB)
CBMM-Memo-062.pdf (9.37 MB) Invariant Recognition Shapes Neural Representations of Visual Input. Annual Review of Vision Science 4, 403 - 422 (2018). annurev-vision-091517-034103.pdf (1.55 MB)
annurev-vision-091517-034103.pdf (1.55 MB) Invariant representations for action recognition in the visual system. Vision Sciences Society 15, (2015).
Invariant recognition drives neural representations of action sequences. PLoS Comp. Bio (2017).
Trading robust representations for sample complexity through self-supervised visual experience. Advances in Neural Information Processing Systems 31 () 9640–9650 (Curran Associates, Inc., 2018). at <http://papers.nips.cc/paper/8170-trading-robust-representations-for-sample-complexity-through-self-supervised-visual-experience.pdf> trading-robust-representations-for-sample-complexity-through-self-supervised-visual-experience.pdf (3.32 MB) NeurIPS2018_Poster.pdf (6.12 MB)
trading-robust-representations-for-sample-complexity-through-self-supervised-visual-experience.pdf (3.32 MB) NeurIPS2018_Poster.pdf (6.12 MB) Neural tuning size is a key factor underlying holistic face processing. (2014). CBMM-Memo-021-1406.3793.pdf (387.79 KB)
CBMM-Memo-021-1406.3793.pdf (387.79 KB) Neural Tuning Size in a Model of Primate Visual Processing Accounts for Three Key Markers of Holistic Face Processing. Public Library of Science | PLoS ONE 1(3): e0150980, (2016). journal.pone_.0150980.PDF (384.15 KB)
journal.pone_.0150980.PDF (384.15 KB) Cascade of neural processing orchestrates cognitive control in human frontal cortex [code]. (2016). at <http://klab.tch.harvard.edu/resources/tangetal_stroop_2016.html>
Recurrent computations for visual pattern completion. Proceedings of the National Academy of Sciences (2018). doi:10.1073/pnas.1719397115 1719397115.full_.pdf (1.1 MB)
1719397115.full_.pdf (1.1 MB) A machine learning approach to predict episodic memory formation. 2016 Annual Conference on Information Science and Systems (CISS) 539 - 544 (2016). doi:10.1109/CISS.2016.7460560
Computational and Cognitive Neuroscience of Vision (Springer Singapore, 2017). at <http://www.springer.com/us/book/9789811002113>
A role for recurrent processing in object completion: neurophysiological, psychophysical and computational evidence. (2014). CBMM-Memo-009.pdf (4.21 MB)
CBMM-Memo-009.pdf (4.21 MB) Spatiotemporal Dynamics Underlying Object Completion in Human Ventral Visual Cortex. Neuron 83, 736 - 748 (2014).
Cascade of neural processing orchestrates cognitive control in human frontal cortex. eLIFE (2016). doi:10.7554/eLife.12352 Manuscript (1.83 MB)
Manuscript (1.83 MB) Cascade of neural processing orchestrates cognitive control in human frontal cortex [dataset]. (2016). at <http://klab.tch.harvard.edu/resources/tangetal_stroop_2016.html>
Predicting episodic memory formation for movie events. Scientific Reports (2016). doi:10.1038/srep30175
Towards an objective characterization of an individual's facial movements using Self-Supervised Person-Specific-Models. arXiv (2022). at <https://arxiv.org/abs/2211.08279>
Improved Measures of Integrated Information. PLOS Computational Biology (2016). doi:10.1371/journal.pcbi.100512310.1371 1601.02626.pdf (3.49 MB)
1601.02626.pdf (3.49 MB) Zero-shot linear combinations of grounded social interactions with Linear Social MDPs. Proceedings of the 37th AAAI Conference on Artificial Intelligence (AAAI) (2023).