# Difference between revisions of "stat946F18"

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[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=stat946F18/Beyond_Word_Importance_Contextual_Decomposition_to_Extract_Interactions_from_LSTMs Summary] | [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=stat946F18/Beyond_Word_Importance_Contextual_Decomposition_to_Extract_Interactions_from_LSTMs Summary] | ||

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− | |Oct 25 || Amirpasha Ghabussi || 2 || | + | |Oct 25 || Amirpasha Ghabussi || 2 || DCN+: Mixed Objective And Deep Residual Coattention for Question Answering || [https://openreview.net/pdf?id=H1meywxRW Paper] || |

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|Oct 25 || Juan Carrillo || 3 || Hierarchical Representations for Efficient Architecture Search || [https://arxiv.org/abs/1711.00436 Paper] || | |Oct 25 || Juan Carrillo || 3 || Hierarchical Representations for Efficient Architecture Search || [https://arxiv.org/abs/1711.00436 Paper] || |

## Revision as of 18:42, 19 October 2018

## Project Proposal

# Paper presentation

Date | Name | Paper number | Title | Link to the paper | Link to the summary |

Feb 15 (example) | Ri Wang | Sequence to sequence learning with neural networks. | Paper | [Summary] | |

Oct 25 | Dhruv Kumar | 1 | Beyond Word Importance: Contextual Decomposition to Extract Interactions from LSTMs | Paper | |

Oct 25 | Amirpasha Ghabussi | 2 | DCN+: Mixed Objective And Deep Residual Coattention for Question Answering | Paper | |

Oct 25 | Juan Carrillo | 3 | Hierarchical Representations for Efficient Architecture Search | Paper | |

Oct 30 | Manpreet Singh Minhas | 1 | End-to-end Active Object Tracking via Reinforcement Learning | Paper | |

Oct 30 | Marvin Pafla | 2 | Fairness Without Demographics in Repeated Loss Minimization | Paper | |

Oct 30 | Glen Chalatov | 3 | Pixels to Graphs by Associative Embedding | Paper | |

Nov 1 | Sriram Ganapathi Subramanian | 1 | Differentiable plasticity: training plastic neural networks with backpropagation | Paper | |

Nov 1 | Hadi Nekoei | 1 | Synthesizing Programs for Images using Reinforced Adversarial Learning | Paper | |

Nov 1 | Henry Chen | 1 | DeepVO: Towards end-to-end visual odometry with deep Recurrent Convolutional Neural Networks | Paper | |

Nov 6 | Nargess Heydari | 2 | |||

Nov 6 | Aravind Ravi | 3 | Towards Image Understanding from Deep Compression Without Decoding | Paper | |

Nov 6 | Ronald Feng | ||||

Nov 8 | Neel Bhatt | 1 | Annotating Object Instances with a Polygon-RNN | Paper | |

Nov 8 | Jacob Manuel | 2 | |||

Nov 8 | Charupriya Sharma | 2 | |||

NOv 13 | Sagar Rajendran | 1 | Zero-Shot Visual Imitation | Paper | |

Nov 13 | Jiazhen Chen | 2 | |||

Nov 13 | Neil Budnarain | 2 | PixelNN: Example-Based Image Synthesis | Paper | |

NOv 15 | Zheng Ma | 3 | Reinforcement Learning of Theorem Proving | Paper | |

Nov 15 | Abdul Khader Naik | 4 | |||

Nov 15 | Johra Muhammad Moosa | 2 | Attend and Predict: Understanding Gene Regulation by Selective Attention on Chromatin | Paper | |

NOv 20 | Zahra Rezapour Siahgourabi | 1 | |||

Nov 20 | Shubham Koundinya | 6 | |||

Nov 20 | Salman Khan | Obfuscated Gradients Give a False Sense of Security: Circumventing Defenses to Adversarial Examples | paper | ||

NOv 22 | Soroush Ameli | 3 | Learning to Navigate in Cities Without a Map | paper | |

Nov 22 | Ivan Li | 23 | Overfitting or perfect fitting? Risk bounds for classification and regression rules that interpolate | Paper | |

Nov 22 | Sigeng Chen | 2 | |||

Nov 27 | Aileen Li | 8 | Spatially Transformed Adversarial Examples | Paper | |

NOv 27 | Xudong Peng | 9 | Multi-Scale Dense Networks for Resource Efficient Image Classification | Paper | |

Nov 27 | Xinyue Zhang | 10 | An Inference-Based Policy Gradient Method for Learning Options | Paper | |

NOv 29 | Junyi Zhang | 11 | |||

Nov 29 | Travis Bender | 12 | Automatic Goal Generation for Reinforcement Learning Agents | Paper | |

Nov 29 | Patrick Li | 12 | Near Optimal Frequent Directions for Sketching Dense and Sparse Matrices | Paper | |

Makup | Ruijie Zhang | 1 | Searching for Efficient Multi-Scale Architectures for Dense Image Prediction | Paper | |

Makup | Ahmed Afify | 2 | Don't Decay the Learning Rate, Increase the Batch Size | Paper | |

Makup | Gaurav Sahu | 3 | TBD | ||

Makup | Kashif Khan | 4 | Wasserstein Auto-Encoders | Paper | |

Makup | Shala Chen | A NEURAL REPRESENTATION OF SKETCH DRAWINGS | |||

Makup | Ki Beom Lee | ||||

Makup | Wesley Fisher | Deep Reinforcement Learning in Continuous Action Spaces: a Case Study in the Game of Simulated Curling | Paper |