stat946F18: Difference between revisions
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|Nov 13 || Neil Budnarain || 18 || Predicting Floor Level For 911 Calls with Neural Networks and Smartphone Sensor Data || [https://openreview.net/pdf?id=ryBnUWb0b Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Predicting_Floor_Level_For_911_Calls_with_Neural_Network_and_Smartphone_Sensor_Data Summary] | |Nov 13 || Neil Budnarain || 18 || Predicting Floor Level For 911 Calls with Neural Networks and Smartphone Sensor Data || [https://openreview.net/pdf?id=ryBnUWb0b Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Predicting_Floor_Level_For_911_Calls_with_Neural_Network_and_Smartphone_Sensor_Data Summary] | ||
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|NOv 15 || Zheng Ma || 19 || Reinforcement Learning of Theorem Proving || [https://arxiv.org/abs/1805.07563 Paper] || | |NOv 15 || Zheng Ma || 19 || Reinforcement Learning of Theorem Proving || [https://arxiv.org/abs/1805.07563 Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Reinforcement_Learning_of_Theorem_Proving Summary] [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:zheng_946_presentation.pdf Slides] | ||
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|Nov 15 || Abdul Khader Naik || 20 || Multi-View Data Generation Without View Supervision || [https://openreview.net/pdf?id=ryRh0bb0Z Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=MULTI-VIEW_DATA_GENERATION_WITHOUT_VIEW_SUPERVISION Summary] | |Nov 15 || Abdul Khader Naik || 20 || Multi-View Data Generation Without View Supervision || [https://openreview.net/pdf?id=ryRh0bb0Z Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=MULTI-VIEW_DATA_GENERATION_WITHOUT_VIEW_SUPERVISION Summary] | ||
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|Nov 15 || Johra Muhammad Moosa || 21 || Attend and Predict: Understanding Gene Regulation by Selective Attention on Chromatin || [https://papers.nips.cc/paper/7255-attend-and-predict-understanding-gene-regulation-by-selective-attention-on-chromatin.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Attend_and_Predict:_Understanding_Gene_Regulation_by_Selective_Attention_on_Chromatin Summary] | |Nov 15 || Johra Muhammad Moosa || 21 || Attend and Predict: Understanding Gene Regulation by Selective Attention on Chromatin || [https://papers.nips.cc/paper/7255-attend-and-predict-understanding-gene-regulation-by-selective-attention-on-chromatin.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Attend_and_Predict:_Understanding_Gene_Regulation_by_Selective_Attention_on_Chromatin Summary] [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:Attend_and_Predict.pdf Slides] | ||
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|NOv 20 || Zahra Rezapour Siahgourabi || 22 ||Robot Learning in Homes: Improving Generalization and Reducing Dataset Bias ||[https://arxiv.org/pdf/1807.07049 Paper] || | |NOv 20 || Zahra Rezapour Siahgourabi || 22 ||Robot Learning in Homes: Improving Generalization and Reducing Dataset Bias ||[https://arxiv.org/pdf/1807.07049 Paper] || | ||
[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Robot_Learning_in_Homes:_Improving_Generalization_and_Reducing_Dataset_Bias Summary] | |||
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|Nov 20 || Shubham Koundinya || 23 || Countering Adversarial Images Using Input Transformations || || | |Nov 20 || Shubham Koundinya || 23 || Countering Adversarial Images Using Input Transformations ||[https://openreview.net/pdf?id=SyJ7ClWCb paper] || | ||
[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Countering_Adversarial_Images_Using_Input_Transformations Summary] | |||
[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:Countering_Adversarial_Images.pdf Slides] | |||
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|Nov 20 || Salman Khan || 24 || Obfuscated Gradients Give a False Sense of Security: Circumventing Defenses to Adversarial Examples || [http://proceedings.mlr.press/v80/athalye18a.html paper] || | |Nov 20 || Salman Khan || 24 || Obfuscated Gradients Give a False Sense of Security: Circumventing Defenses to Adversarial Examples || [http://proceedings.mlr.press/v80/athalye18a.html paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Obfuscated_Gradients_Give_a_False_Sense_of_Security_Circumventing_Defenses_to_Adversarial_Examples Summary] | ||
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|NOv 22 ||Soroush Ameli || 25 || Learning to Navigate in Cities Without a Map || [https://arxiv.org/abs/1804.00168 paper] || | |NOv 22 ||Soroush Ameli || 25 || Learning to Navigate in Cities Without a Map || [https://arxiv.org/abs/1804.00168 paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Learning_to_Navigate_in_Cities_Without_a_Map Summary] | ||
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|Nov 22 ||Ivan Li || 26 || Mapping Images to Scene Graphs with Permutation-Invariant Structured Prediction || [https://arxiv.org/pdf/1802.05451v3.pdf Paper] || | |Nov 22 ||Ivan Li || 26 || Mapping Images to Scene Graphs with Permutation-Invariant Structured Prediction || [https://arxiv.org/pdf/1802.05451v3.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Mapping_Images_to_Scene_Graphs_with_Permutation-Invariant_Structured_Prediction Summary] | ||
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|Nov 22 ||Sigeng Chen || 27 || || || | |Nov 22 ||Sigeng Chen || 27 ||Conditional Neural Processes || [http://proceedings.mlr.press/v80/garnelo18a/garnelo18a.pdf Paper] ||[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=conditional_neural_process Summary] | ||
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|Nov 27 || Aileen Li || 28 || | |Nov 27 || Aileen Li || 28 || Unsupervised Neural Machine Translation ||[https://openreview.net/pdf?id=Sy2ogebAW Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Unsupervised_Neural_Machine_Translation Summary] | ||
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|Nov 27 ||Xudong Peng || 29 || | |Nov 27 ||Xudong Peng || 29 || Visual Reinforcement Learning with Imagined Goals || [https://arxiv.org/abs/1807.04742 Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Visual_Reinforcement_Learning_with_Imagined_Goals Summary] | ||
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|Nov 27 ||Xinyue Zhang || 30 || | |Nov 27 ||Xinyue Zhang || 30 || Policy Optimization with Demonstrations || [http://proceedings.mlr.press/v80/kang18a/kang18a.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=policy_optimization_with_demonstrations Summary] | ||
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| | |NOv 29 ||Junyi Zhang || 31 || Autoregressive Convolutional Neural Networks for Asynchronous Time Series || [http://proceedings.mlr.press/v80/binkowski18a/binkowski18a.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=stat946F18/Autoregressive_Convolutional_Neural_Networks_for_Asynchronous_Time_Series Summary] | ||
[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:SOCNN.pdf Slides] | |||
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|Nov 29 || | |Nov 29 ||Travis Bender || 32 || ShakeDrop Regularization || [https://arxiv.org/pdf/1802.02375.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=ShakeDrop_Regularization Summary] [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:ShakeDrop_Regularization.pdf Slides] | ||
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| | |Nov 29 ||Patrick Li || 33 || Dynamic Routing Between Capsules || [https://arxiv.org/pdf/1710.09829.pdf Paper] ||[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=CapsuleNets Summary] [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=File:STAT946_Presentation1.pdf Slides]|| | ||
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| | |Nov 30 || Jiazhen Chen || 34 || Learn What Not to Learn: Action Elimination with Deep Reinforcement Learning || [https://arxiv.org/abs/1809.02121 Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=learn_what_not_to_learn Summary] | ||
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| | |Nov 30 || Gaurav Sahu || 35 || Fix your classifier: the marginal value of training the last weight layer || [https://openreview.net/pdf?id=S1Dh8Tg0- Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Fix_your_classifier:_the_marginal_value_of_training_the_last_weight_layer Summary] | ||
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| | |Nov 23 || Kashif Khan || 36 || Wasserstein Auto-Encoders || [https://arxiv.org/pdf/1711.01558.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Wasserstein_Auto-encoders Summary] | ||
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| | |Nov 23 || Shala Chen || 37 || A Neural Representation of Sketch Drawings || [https://arxiv.org/pdf/1704.03477.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=a_neural_representation_of_sketch_drawings Summary] | ||
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| | |Nov 30 || Ki Beom Lee || 38 || Detecting Statistical Interactions from Neural Network Weights|| [https://openreview.net/forum?id=ByOfBggRZ Paper] || | ||
[https://wiki.math.uwaterloo.ca/statwiki/index.php?title=DETECTING_STATISTICAL_INTERACTIONS_FROM_NEURAL_NETWORK_WEIGHTS Summary] | |||
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|Nov 23 || Wesley Fisher || 39 || Deep Reinforcement Learning in Continuous Action Spaces: a Case Study in the Game of Simulated Curling || [http://proceedings.mlr.press/v80/lee18b/lee18b.pdf Paper] || [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=Deep_Reinforcement_Learning_in_Continuous_Action_Spaces_a_Case_Study_in_the_Game_of_Simulated_Curling Summary] | |||
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||Nov 30|| Ahmed Afify || 40 ||Don't Decay the Learning Rate, Increase the Batch Size || [https://openreview.net/pdf?id=B1Yy1BxCZ Paper]|| [https://wiki.math.uwaterloo.ca/statwiki/index.php?title=DON'T_DECAY_THE_LEARNING_RATE_,_INCREASE_THE_BATCH_SIZE Summary] | |||
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Latest revision as of 03:22, 2 December 2018
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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 | 4 | End-to-end Active Object Tracking via Reinforcement Learning | Paper | Summary | |
Oct 30 | Marvin Pafla | 5 | Fairness Without Demographics in Repeated Loss Minimization | Paper | Summary | |
Oct 30 | Glen Chalatov | 6 | Pixels to Graphs by Associative Embedding | Paper | ||
Nov 1 | Sriram Ganapathi Subramanian | 7 | Differentiable plasticity: training plastic neural networks with backpropagation | Paper | Summary | |
Nov 1 | Hadi Nekoei | 8 | Synthesizing Programs for Images using Reinforced Adversarial Learning | Paper | Summary | |
Nov 1 | Henry Chen | 9 | DeepVO: Towards end-to-end visual odometry with deep Recurrent Convolutional Neural Networks | Paper | ||
Nov 6 | Nargess Heydari | 10 | Wavelet Pooling For Convolutional Neural Networks Networks | Paper | Summary Slides | |
Nov 6 | Aravind Ravi | 11 | Towards Image Understanding from Deep Compression Without Decoding | Paper | Summary | |
Nov 6 | Ronald Feng | 12 | Learning to Teach | Paper | Summary | |
Nov 8 | Neel Bhatt | 13 | Annotating Object Instances with a Polygon-RNN | Paper | Summary Slides | |
Nov 8 | Jacob Manuel | 14 | Co-teaching: Robust Training Deep Neural Networks with Extremely Noisy Labels | Paper | Summary Slides | |
Nov 8 | Charupriya Sharma | 15 | A Bayesian Perspective on Generalization and Stochastic Gradient Descent | Paper | Summary | |
NOv 13 | Sagar Rajendran | 16 | Zero-Shot Visual Imitation | Paper | Summary | |
Nov 13 | Ruijie Zhang | 17 | Searching for Efficient Multi-Scale Architectures for Dense Image Prediction | Paper | Summary | |
Nov 13 | Neil Budnarain | 18 | Predicting Floor Level For 911 Calls with Neural Networks and Smartphone Sensor Data | Paper | Summary | |
NOv 15 | Zheng Ma | 19 | Reinforcement Learning of Theorem Proving | Paper | Summary Slides | |
Nov 15 | Abdul Khader Naik | 20 | Multi-View Data Generation Without View Supervision | Paper | Summary | |
Nov 15 | Johra Muhammad Moosa | 21 | Attend and Predict: Understanding Gene Regulation by Selective Attention on Chromatin | Paper | Summary Slides | |
NOv 20 | Zahra Rezapour Siahgourabi | 22 | Robot Learning in Homes: Improving Generalization and Reducing Dataset Bias | Paper | ||
Nov 20 | Shubham Koundinya | 23 | Countering Adversarial Images Using Input Transformations | paper | ||
Nov 20 | Salman Khan | 24 | Obfuscated Gradients Give a False Sense of Security: Circumventing Defenses to Adversarial Examples | paper | Summary | |
NOv 22 | Soroush Ameli | 25 | Learning to Navigate in Cities Without a Map | paper | Summary | |
Nov 22 | Ivan Li | 26 | Mapping Images to Scene Graphs with Permutation-Invariant Structured Prediction | Paper | Summary | |
Nov 22 | Sigeng Chen | 27 | Conditional Neural Processes | Paper | Summary | |
Nov 27 | Aileen Li | 28 | Unsupervised Neural Machine Translation | Paper | Summary | |
Nov 27 | Xudong Peng | 29 | Visual Reinforcement Learning with Imagined Goals | Paper | Summary | |
Nov 27 | Xinyue Zhang | 30 | Policy Optimization with Demonstrations | Paper | Summary | |
NOv 29 | Junyi Zhang | 31 | Autoregressive Convolutional Neural Networks for Asynchronous Time Series | Paper | Summary | |
Nov 29 | Travis Bender | 32 | ShakeDrop Regularization | Paper | Summary Slides | |
Nov 29 | Patrick Li | 33 | Dynamic Routing Between Capsules | Paper | Summary Slides | |
Nov 30 | Jiazhen Chen | 34 | Learn What Not to Learn: Action Elimination with Deep Reinforcement Learning | Paper | Summary | |
Nov 30 | Gaurav Sahu | 35 | Fix your classifier: the marginal value of training the last weight layer | Paper | Summary | |
Nov 23 | Kashif Khan | 36 | Wasserstein Auto-Encoders | Paper | Summary | |
Nov 23 | Shala Chen | 37 | A Neural Representation of Sketch Drawings | Paper | Summary | |
Nov 30 | Ki Beom Lee | 38 | Detecting Statistical Interactions from Neural Network Weights | Paper | ||
Nov 23 | Wesley Fisher | 39 | Deep Reinforcement Learning in Continuous Action Spaces: a Case Study in the Game of Simulated Curling | Paper | Summary | |
Nov 30 | Ahmed Afify | 40 | Don't Decay the Learning Rate, Increase the Batch Size | Paper | Summary |