Datasets:
witchling22
/
tokenized_dataset_bart

Dataset card Viewer Files Community
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['We present an approach for expanding taxonomies with synonyms, or aliases.', 'We target large shopping taxonomies, with thousands of nodes.', 'A comprehensive set of entity aliases is an important component of identifying entities in unstructured text such as product reviews or search queries.', 'Our method consists of two stages: we generate synonym candidates from WordNet and shopping search queries, then use a binary classifier to filter candidates.', 'We process taxonomies with thousands of synonyms in order to generate over 90,000 synonyms.', 'We show that using the taxonomy to derive contextual features improves classification performance over using features from the target node alone.We show that our approach has potential for transfer learning between different taxonomy domains, which reduces the need to collect training data for new taxonomies.']
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rJx2g-qaTm
['We use machine learning to generate synonyms for large shopping taxonomies.']
We present an approach for expanding taxonomies with synonyms, or aliases., We target large shopping taxonomies, with thousands of nodes., A comprehensive set of entity aliases is an important component of identifying entities in unstructured text such as product reviews or search queries., Our method consists of two stages: we generate synonym candidates from WordNet and shopping search queries, then use a binary classifier to filter candidates., We process taxonomies with thousands of synonyms in order to generate over 90,000 synonyms., We show that using the taxonomy to derive contextual features improves classification performance over using features from the target node alone.We show that our approach has potential for transfer learning between different taxonomy domains, which reduces the need to collect training data for new taxonomies.
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['Relational reasoning, the ability to model interactions and relations between objects, is valuable for robust multi-object tracking and pivotal for trajectory prediction.', 'In this paper, we propose MOHART, a class-agnostic, end-to-end multi-object tracking and trajectory prediction algorithm, which explicitly accounts for permutation invariance in its relational reasoning.', 'We explore a number of permutation invariant architectures and show that multi-headed self-attention outperforms the provided baselines and better accounts for complex physical interactions in a challenging toy experiment.', 'We show on three real-world tracking datasets that adding relational reasoning capabilities in this way increases the tracking and trajectory prediction performance, particularly in the presence of ego-motion, occlusions, crowded scenes, and faulty sensor inputs.', 'To the best of our knowledge, MOHART is the first fully end-to-end multi-object tracking from vision approach applied to real-world data reported in the literature.']
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['MOHART uses a self-attention mechanism to perform relational reasoning in multi-object tracking.']
Relational reasoning, the ability to model interactions and relations between objects, is valuable for robust multi-object tracking and pivotal for trajectory prediction., In this paper, we propose MOHART, a class-agnostic, end-to-end multi-object tracking and trajectory prediction algorithm, which explicitly accounts for permutation invariance in its relational reasoning., We explore a number of permutation invariant architectures and show that multi-headed self-attention outperforms the provided baselines and better accounts for complex physical interactions in a challenging toy experiment., We show on three real-world tracking datasets that adding relational reasoning capabilities in this way increases the tracking and trajectory prediction performance, particularly in the presence of ego-motion, occlusions, crowded scenes, and faulty sensor inputs., To the best of our knowledge, MOHART is the first fully end-to-end multi-object tracking from vision approach applied to real-world data reported in the literature.
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['We investigate the combination of actor-critic reinforcement learning algorithms with uniform large-scale experience replay and propose solutions for two challenges:', '(a) efficient actor-critic learning with experience replay', '(b) stability of very off-policy learning.', 'We employ those insights to accelerate hyper-parameter sweeps in which all participating agents run concurrently and share their experience via a common replay module.\n\n', 'To this end we analyze the bias-variance tradeoffs in V-trace, a form of importance sampling for actor-critic methods.', 'Based on our analysis, we then argue for mixing experience sampled from replay with on-policy experience, and propose a new trust region scheme that scales effectively to data distributions where V-trace becomes unstable.\n\n', 'We provide extensive empirical validation of the proposed solution.', 'We further show the benefits of this setup by demonstrating state-of-the-art data efficiency on Atari among agents trained up until 200M environment frames.']
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HygaikBKvS
['We investigate and propose solutions for two challenges in reinforcement learning: (a) efficient actor-critic learning with experience replay (b) stability of very off-policy learning.']
We investigate the combination of actor-critic reinforcement learning algorithms with uniform large-scale experience replay and propose solutions for two challenges:, (a) efficient actor-critic learning with experience replay, (b) stability of very off-policy learning., We employ those insights to accelerate hyper-parameter sweeps in which all participating agents run concurrently and share their experience via a common replay module. , To this end we analyze the bias-variance tradeoffs in V-trace, a form of importance sampling for actor-critic methods., Based on our analysis, we then argue for mixing experience sampled from replay with on-policy experience, and propose a new trust region scheme that scales effectively to data distributions where V-trace becomes unstable. , We provide extensive empirical validation of the proposed solution., We further show the benefits of this setup by demonstrating state-of-the-art data efficiency on Atari among agents trained up until 200M environment frames.
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['Stochastic gradient descent (SGD) is the workhorse of modern machine learning.', 'Sometimes, there are many different potential gradient estimators that can be used.', 'When so, choosing the one with the best tradeoff between cost and variance is important.', 'This paper analyzes the convergence rates of SGD as a function of time, rather than iterations.', 'This results in a simple rule to select the estimator that leads to the best optimization convergence guarantee.', 'This choice is the same for different variants of SGD, and with different assumptions about the objective (e.g. convexity or smoothness).', 'Inspired by this principle, we propose a technique to automatically select an estimator when a finite pool of estimators is given.', 'Then, we extend to infinite pools of estimators, where each one is indexed by control variate weights.', 'This is enabled by a reduction to a mixed-integer quadratic program.', 'Empirically, automatically choosing an estimator performs comparably to the best estimator chosen with hindsight.']
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SygQKy3EFB
['We propose a gradient estimator selection algorithm with the aim on improving optimization efficiency.']
Stochastic gradient descent (SGD) is the workhorse of modern machine learning., Sometimes, there are many different potential gradient estimators that can be used., When so, choosing the one with the best tradeoff between cost and variance is important., This paper analyzes the convergence rates of SGD as a function of time, rather than iterations., This results in a simple rule to select the estimator that leads to the best optimization convergence guarantee., This choice is the same for different variants of SGD, and with different assumptions about the objective (e.g. convexity or smoothness)., Inspired by this principle, we propose a technique to automatically select an estimator when a finite pool of estimators is given., Then, we extend to infinite pools of estimators, where each one is indexed by control variate weights., This is enabled by a reduction to a mixed-integer quadratic program., Empirically, automatically choosing an estimator performs comparably to the best estimator chosen with hindsight.
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['We study the problem of alleviating the instability issue in the GAN training procedure via new architecture design.', 'The discrepancy between the minimax and maximin objective values could serve as a proxy for the difficulties that the alternating gradient descent encounters in the optimization of GANs.', 'In this work, we give new results on the benefits of multi-generator architecture of GANs.', 'We show that the minimax gap shrinks to \\epsilon as the number of generators increases with rate O(1/\\epsilon).', 'This improves over the best-known result of O(1/\\epsilon^2).', 'At the core of our techniques is a novel application of Shapley-Folkman lemma to the generic minimax problem, where in the literature the technique was only known to work when the objective function is restricted to the Lagrangian function of a constraint optimization problem.', 'Our proposed Stackelberg GAN performs well experimentally in both synthetic and real-world datasets, improving Frechet Inception Distance by 14.61% over the previous multi-generator GANs on the benchmark datasets.']
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SJxCsj0qYX
['We study the problem of alleviating the instability issue in the GAN training procedure via new architecture design, with theoretical guarantees.']
We study the problem of alleviating the instability issue in the GAN training procedure via new architecture design., The discrepancy between the minimax and maximin objective values could serve as a proxy for the difficulties that the alternating gradient descent encounters in the optimization of GANs., In this work, we give new results on the benefits of multi-generator architecture of GANs., We show that the minimax gap shrinks to \epsilon as the number of generators increases with rate O(1/\epsilon)., This improves over the best-known result of O(1/\epsilon^2)., At the core of our techniques is a novel application of Shapley-Folkman lemma to the generic minimax problem, where in the literature the technique was only known to work when the objective function is restricted to the Lagrangian function of a constraint optimization problem., Our proposed Stackelberg GAN performs well experimentally in both synthetic and real-world datasets, improving Frechet Inception Distance by 14.61% over the previous multi-generator GANs on the benchmark datasets.
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['\nNesterov SGD is widely used for training modern neural networks and other machine learning models.', 'Yet, its advantages over SGD have not been theoretically clarified.', 'Indeed, as we show in this paper, both theoretically and empirically, Nesterov SGD with any parameter selection does not in general provide acceleration over ordinary SGD.', 'Furthermore, Nesterov SGD may diverge for step sizes that ensure convergence of ordinary SGD.', "This is in contrast to the classical results in the deterministic setting, where the same step size ensures accelerated convergence of the Nesterov's method over optimal gradient descent.\n\n", 'To address the non-acceleration issue, we introduce a compensation term to Nesterov SGD.', 'The resulting algorithm, which we call MaSS, converges for same step sizes as SGD.', 'We prove that MaSS obtains an accelerated convergence rates over SGD for any mini-batch size in the linear setting. ', "For full batch, the convergence rate of MaSS matches the well-known accelerated rate of the Nesterov's method. \n\n", 'We also analyze the practically important question of the dependence of the convergence rate and optimal hyper-parameters on the mini-batch size, demonstrating three distinct regimes: linear scaling, diminishing returns and saturation.\n\n', 'Experimental evaluation of MaSS for several standard architectures of deep networks, including ResNet and convolutional networks, shows improved performance over SGD, Nesterov SGD and Adam.']
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r1gixp4FPH
['This work proves the non-acceleration of Nesterov SGD with any hyper-parameters, and proposes new algorithm which provably accelerates SGD in the over-parameterized setting.']
Nesterov SGD is widely used for training modern neural networks and other machine learning models., Yet, its advantages over SGD have not been theoretically clarified., Indeed, as we show in this paper, both theoretically and empirically, Nesterov SGD with any parameter selection does not in general provide acceleration over ordinary SGD., Furthermore, Nesterov SGD may diverge for step sizes that ensure convergence of ordinary SGD., This is in contrast to the classical results in the deterministic setting, where the same step size ensures accelerated convergence of the Nesterov's method over optimal gradient descent. , To address the non-acceleration issue, we introduce a compensation term to Nesterov SGD., The resulting algorithm, which we call MaSS, converges for same step sizes as SGD., We prove that MaSS obtains an accelerated convergence rates over SGD for any mini-batch size in the linear setting. , For full batch, the convergence rate of MaSS matches the well-known accelerated rate of the Nesterov's method. , We also analyze the practically important question of the dependence of the convergence rate and optimal hyper-parameters on the mini-batch size, demonstrating three distinct regimes: linear scaling, diminishing returns and saturation. , Experimental evaluation of MaSS for several standard architectures of deep networks, including ResNet and convolutional networks, shows improved performance over SGD, Nesterov SGD and Adam.
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['We propose the Fixed Grouping Layer (FGL); a novel feedforward layer designed to incorporate the inductive bias of structured smoothness into a deep learning model.', 'FGL achieves this goal by connecting nodes across layers based on spatial similarity.', 'The use of structured smoothness, as implemented by FGL, is motivated by applications to structured spatial data, which is, in turn, motivated by domain knowledge.', 'The proposed model architecture outperforms conventional neural network architectures across a variety of simulated and real datasets with structured smoothness.']
[1, 0, 0, 0]
[0.6285714507102966, 0.0, 0.12121211737394333, 0.25]
Hklr204Fvr
['A feedforward layer to incorporate structured smoothness into a deep learning model']
We propose the Fixed Grouping Layer (FGL); a novel feedforward layer designed to incorporate the inductive bias of structured smoothness into a deep learning model., FGL achieves this goal by connecting nodes across layers based on spatial similarity., The use of structured smoothness, as implemented by FGL, is motivated by applications to structured spatial data, which is, in turn, motivated by domain knowledge., The proposed model architecture outperforms conventional neural network architectures across a variety of simulated and real datasets with structured smoothness.
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["Convolutional networks are not aware of an object's geometric variations, which leads to inefficient utilization of model and data capacity.", 'To overcome this issue, recent works on deformation modeling seek to spatially reconfigure the data towards a common arrangement such that semantic recognition suffers less from deformation.', 'This is typically done by augmenting static operators with learned free-form sampling grids in the image space, dynamically tuned to the data and task for adapting the receptive field.', 'Yet adapting the receptive field does not quite reach the actual goal -- what really matters to the network is the *effective* receptive field (ERF), which reflects how much each pixel contributes.', 'It is thus natural to design other approaches to adapt the ERF directly during runtime.', 'In this work, we instantiate one possible solution as Deformable Kernels (DKs), a family of novel and generic convolutional operators for handling object deformations by directly adapting the ERF while leaving the receptive field untouched.', 'At the heart of our method is the ability to resample the original kernel space towards recovering the deformation of objects.', 'This approach is justified with theoretical insights that the ERF is strictly determined by data sampling locations and kernel values.', 'We implement DKs as generic drop-in replacements of rigid kernels and conduct a series of empirical studies whose results conform with our theories.', 'Over several tasks and standard base models, our approach compares favorably against prior works that adapt during runtime.', 'In addition, further experiments suggest a working mechanism orthogonal and complementary to previous works.']
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SkxSv6VFvS
["Don't deform your convolutions -- deform your kernels."]
Convolutional networks are not aware of an object's geometric variations, which leads to inefficient utilization of model and data capacity., To overcome this issue, recent works on deformation modeling seek to spatially reconfigure the data towards a common arrangement such that semantic recognition suffers less from deformation., This is typically done by augmenting static operators with learned free-form sampling grids in the image space, dynamically tuned to the data and task for adapting the receptive field., Yet adapting the receptive field does not quite reach the actual goal -- what really matters to the network is the *effective* receptive field (ERF), which reflects how much each pixel contributes., It is thus natural to design other approaches to adapt the ERF directly during runtime., In this work, we instantiate one possible solution as Deformable Kernels (DKs), a family of novel and generic convolutional operators for handling object deformations by directly adapting the ERF while leaving the receptive field untouched., At the heart of our method is the ability to resample the original kernel space towards recovering the deformation of objects., This approach is justified with theoretical insights that the ERF is strictly determined by data sampling locations and kernel values., We implement DKs as generic drop-in replacements of rigid kernels and conduct a series of empirical studies whose results conform with our theories., Over several tasks and standard base models, our approach compares favorably against prior works that adapt during runtime., In addition, further experiments suggest a working mechanism orthogonal and complementary to previous works.
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['Inferring the structural properties of a protein from its amino acid sequence is a challenging yet important problem in biology.', 'Structures are not known for the vast majority of protein sequences, but structure is critical for understanding function.', 'Existing approaches for detecting structural similarity between proteins from sequence are unable to recognize and exploit structural patterns when sequences have diverged too far, limiting our ability to transfer knowledge between structurally related proteins.', 'We newly approach this problem through the lens of representation learning.', 'We introduce a framework that maps any protein sequence to a sequence of vector embeddings --- one per amino acid position --- that encode structural information.', 'We train bidirectional long short-term memory (LSTM) models on protein sequences with a two-part feedback mechanism that incorporates information from', '(i) global structural similarity between proteins and', '(ii) pairwise residue contact maps for individual proteins.', 'To enable learning from structural similarity information, we define a novel similarity measure between arbitrary-length sequences of vector embeddings based on a soft symmetric alignment (SSA) between them.', 'Our method is able to learn useful position-specific embeddings despite lacking direct observations of position-level correspondence between sequences.', 'We show empirically that our multi-task framework outperforms other sequence-based methods and even a top-performing structure-based alignment method when predicting structural similarity, our goal.', 'Finally, we demonstrate that our learned embeddings can be transferred to other protein sequence problems, improving the state-of-the-art in transmembrane domain prediction.']
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SygLehCqtm
['We present a method for learning protein sequence embedding models using structural information in the form of global structural similarity between proteins and within protein residue-residue contacts.']
Inferring the structural properties of a protein from its amino acid sequence is a challenging yet important problem in biology., Structures are not known for the vast majority of protein sequences, but structure is critical for understanding function., Existing approaches for detecting structural similarity between proteins from sequence are unable to recognize and exploit structural patterns when sequences have diverged too far, limiting our ability to transfer knowledge between structurally related proteins., We newly approach this problem through the lens of representation learning., We introduce a framework that maps any protein sequence to a sequence of vector embeddings --- one per amino acid position --- that encode structural information., We train bidirectional long short-term memory (LSTM) models on protein sequences with a two-part feedback mechanism that incorporates information from, (i) global structural similarity between proteins and, (ii) pairwise residue contact maps for individual proteins., To enable learning from structural similarity information, we define a novel similarity measure between arbitrary-length sequences of vector embeddings based on a soft symmetric alignment (SSA) between them., Our method is able to learn useful position-specific embeddings despite lacking direct observations of position-level correspondence between sequences., We show empirically that our multi-task framework outperforms other sequence-based methods and even a top-performing structure-based alignment method when predicting structural similarity, our goal., Finally, we demonstrate that our learned embeddings can be transferred to other protein sequence problems, improving the state-of-the-art in transmembrane domain prediction.
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['Inspired by the adaptation phenomenon of biological neuronal firing, we propose regularity normalization: a reparameterization of the activation in the neural network that take into account the statistical regularity in the implicit space.', 'By considering the neural network optimization process as a model selection problem, the implicit space is constrained by the normalizing factor, the minimum description length of the optimal universal code.', 'We introduce an incremental version of computing this universal code as normalized maximum likelihood and demonstrated its flexibility to include data prior such as top-down attention and other oracle information and its compatibility to be incorporated into batch normalization and layer normalization.', 'The preliminary results showed that the proposed method outperforms existing normalization methods in tackling the limited and imbalanced data from a non-stationary distribution benchmarked on computer vision task.', 'As an unsupervised attention mechanism given input data, this biologically plausible normalization has the potential to deal with other complicated real-world scenarios as well as reinforcement learning setting where the rewards are sparse and non-uniform.', 'Further research is proposed to discover these scenarios and explore the behaviors among different variants.']
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HklJQ1JEDE
['Considering neural network optimization process as a model selection problem, we introduce a biological plausible normalization method that extracts statistical regularity under MDL principle to tackle imbalanced and limited data issue.']
Inspired by the adaptation phenomenon of biological neuronal firing, we propose regularity normalization: a reparameterization of the activation in the neural network that take into account the statistical regularity in the implicit space., By considering the neural network optimization process as a model selection problem, the implicit space is constrained by the normalizing factor, the minimum description length of the optimal universal code., We introduce an incremental version of computing this universal code as normalized maximum likelihood and demonstrated its flexibility to include data prior such as top-down attention and other oracle information and its compatibility to be incorporated into batch normalization and layer normalization., The preliminary results showed that the proposed method outperforms existing normalization methods in tackling the limited and imbalanced data from a non-stationary distribution benchmarked on computer vision task., As an unsupervised attention mechanism given input data, this biologically plausible normalization has the potential to deal with other complicated real-world scenarios as well as reinforcement learning setting where the rewards are sparse and non-uniform., Further research is proposed to discover these scenarios and explore the behaviors among different variants.
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['In this paper we study generative modeling via autoencoders while using the elegant geometric properties of the optimal transport (OT) problem and the Wasserstein distances.', 'We introduce Sliced-Wasserstein Autoencoders (SWAE), which are generative models that enable one to shape the distribution of the latent space into any samplable probability distribution without the need for training an adversarial network or defining a closed-form for the distribution.', 'In short, we regularize the autoencoder loss with the sliced-Wasserstein distance between the distribution of the encoded training samples and a predefined samplable distribution.', 'We show that the proposed formulation has an efficient numerical solution that provides similar capabilities to Wasserstein Autoencoders (WAE) and Variational Autoencoders (VAE), while benefiting from an embarrassingly simple implementation. \n']
[0, 1, 0, 0]
[0.06451612710952759, 0.1428571343421936, 0.0714285671710968, 0.0]
B1VPIA7iM
['"Generative modeling with no need for adversarial training"']
In this paper we study generative modeling via autoencoders while using the elegant geometric properties of the optimal transport (OT) problem and the Wasserstein distances., We introduce Sliced-Wasserstein Autoencoders (SWAE), which are generative models that enable one to shape the distribution of the latent space into any samplable probability distribution without the need for training an adversarial network or defining a closed-form for the distribution., In short, we regularize the autoencoder loss with the sliced-Wasserstein distance between the distribution of the encoded training samples and a predefined samplable distribution., We show that the proposed formulation has an efficient numerical solution that provides similar capabilities to Wasserstein Autoencoders (WAE) and Variational Autoencoders (VAE), while benefiting from an embarrassingly simple implementation.
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['The goal of imitation learning (IL) is to learn a good policy from high-quality demonstrations.', 'However, the quality of demonstrations in reality can be diverse, since it is easier and cheaper to collect demonstrations from a mix of experts and amateurs.', "IL in such situations can be challenging, especially when the level of demonstrators' expertise is unknown.", "We propose a new IL paradigm called Variational Imitation Learning with Diverse-quality demonstrations (VILD), where we explicitly model the level of demonstrators' expertise with a probabilistic graphical model and estimate it along with a reward function.", 'We show that a naive estimation approach is not suitable to large state and action spaces, and fix this issue by using a variational approach that can be easily implemented using existing reinforcement learning methods.', 'Experiments on continuous-control benchmarks demonstrate that VILD outperforms state-of-the-art methods.', 'Our work enables scalable and data-efficient IL under more realistic settings than before.']
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['We propose an imitation learning method to learn from diverse-quality demonstrations collected by demonstrators with different level of expertise.']
The goal of imitation learning (IL) is to learn a good policy from high-quality demonstrations., However, the quality of demonstrations in reality can be diverse, since it is easier and cheaper to collect demonstrations from a mix of experts and amateurs., IL in such situations can be challenging, especially when the level of demonstrators' expertise is unknown., We propose a new IL paradigm called Variational Imitation Learning with Diverse-quality demonstrations (VILD), where we explicitly model the level of demonstrators' expertise with a probabilistic graphical model and estimate it along with a reward function., We show that a naive estimation approach is not suitable to large state and action spaces, and fix this issue by using a variational approach that can be easily implemented using existing reinforcement learning methods., Experiments on continuous-control benchmarks demonstrate that VILD outperforms state-of-the-art methods., Our work enables scalable and data-efficient IL under more realistic settings than before.
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['With a growing number of available services, each having slightly different parameters, preconditions and effects, automated planning on general semantic services become highly relevant.', 'However, most exiting planners only consider PDDL, or if they claim to use OWL-S, they usually translate it to PDDL, losing much of the semantics on the way.\n', 'In this paper, we propose a new domain-independent heuristic based on a semantic distance that can be used by generic planning algorithms such as A* for automated planning of semantic services described with OWL-S.', 'For the heuristic to include more relevant information we calculate the heuristic at runtime.', 'Using this heuristic, we are able to produce better results (fewer expanded states) in less time than with established techniques.']
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rJMK4bD6vE
['Describing a semantic heuristics which builds upon an OWL-S service description and uses word and sentence distance measures to evaluate the usefulness of services for a given goal. ']
With a growing number of available services, each having slightly different parameters, preconditions and effects, automated planning on general semantic services become highly relevant., However, most exiting planners only consider PDDL, or if they claim to use OWL-S, they usually translate it to PDDL, losing much of the semantics on the way. , In this paper, we propose a new domain-independent heuristic based on a semantic distance that can be used by generic planning algorithms such as A* for automated planning of semantic services described with OWL-S., For the heuristic to include more relevant information we calculate the heuristic at runtime., Using this heuristic, we are able to produce better results (fewer expanded states) in less time than with established techniques.
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['In colored graphs, node classes are often associated with either their neighbors class or with information not incorporated in the graph associated with each node.', 'We here propose that node classes are also associated with topological features of the nodes.', 'We use this association to improve Graph machine learning in general and specifically, Graph Convolutional Networks (GCN). \n\n', 'First, we show that even in the absence of any external information on nodes, a good accuracy can be obtained on the prediction of the node class using either topological features, or using the neighbors class as an input to a GCN.', 'This accuracy is slightly less than the one that can be obtained using content based GCN.\n\n', 'Secondly, we show that explicitly adding the topology as an input to the GCN does not improve the accuracy when combined with external information on nodes.', 'However, adding an additional adjacency matrix with edges between distant nodes with similar topology to the GCN does significantly improve its accuracy, leading to results better than all state of the art methods in multiple datasets.']
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ryey1TNKvH
['Topology-Based Graph Convolutional Network (GCN)']
In colored graphs, node classes are often associated with either their neighbors class or with information not incorporated in the graph associated with each node., We here propose that node classes are also associated with topological features of the nodes., We use this association to improve Graph machine learning in general and specifically, Graph Convolutional Networks (GCN). , First, we show that even in the absence of any external information on nodes, a good accuracy can be obtained on the prediction of the node class using either topological features, or using the neighbors class as an input to a GCN., This accuracy is slightly less than the one that can be obtained using content based GCN. , Secondly, we show that explicitly adding the topology as an input to the GCN does not improve the accuracy when combined with external information on nodes., However, adding an additional adjacency matrix with edges between distant nodes with similar topology to the GCN does significantly improve its accuracy, leading to results better than all state of the art methods in multiple datasets.
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['Flies and mice are species separated by 600 million years of evolution, yet have evolved olfactory systems that share many similarities in their anatomic and functional organization.', 'What functions do these shared anatomical and functional features serve, and are they optimal for odor sensing?', 'In this study, we address the optimality of evolutionary design in olfactory circuits by studying artificial neural networks trained to sense odors.', 'We found that artificial neural networks quantitatively recapitulate structures inherent in the olfactory system, including the formation of glomeruli onto a compression layer and sparse and random connectivity onto an expansion layer.', 'Finally, we offer theoretical justifications for each result.', 'Our work offers a framework to explain the evolutionary convergence of olfactory circuits, and gives insight and logic into the anatomic and functional structure of the olfactory system.']
[0, 0, 1, 0, 0, 0]
[0.2978723347187042, 0.05405404791235924, 0.41860464215278625, 0.3265306055545807, 0.0, 0.23255813121795654]
BylUXXFI8S
['Artificial neural networks evolved the same structures present in the olfactory systems of flies and mice after being trained to classify odors']
Flies and mice are species separated by 600 million years of evolution, yet have evolved olfactory systems that share many similarities in their anatomic and functional organization., What functions do these shared anatomical and functional features serve, and are they optimal for odor sensing?, In this study, we address the optimality of evolutionary design in olfactory circuits by studying artificial neural networks trained to sense odors., We found that artificial neural networks quantitatively recapitulate structures inherent in the olfactory system, including the formation of glomeruli onto a compression layer and sparse and random connectivity onto an expansion layer., Finally, we offer theoretical justifications for each result., Our work offers a framework to explain the evolutionary convergence of olfactory circuits, and gives insight and logic into the anatomic and functional structure of the olfactory system.
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['The recent direction of unpaired image-to-image translation is on one hand very exciting as it alleviates the big burden in obtaining label-intensive pixel-to-pixel supervision, but it is on the other hand not fully satisfactory due to the presence of artifacts and degenerated transformations.', 'In this paper, we take a manifold view of the problem by introducing a smoothness term over the sample graph to attain harmonic functions to enforce consistent mappings during the translation.', 'We develop HarmonicGAN to learn bi-directional translations between the source and the target domains.', 'With the help of similarity-consistency, the inherent self-consistency property of samples can be maintained.', 'Distance metrics defined on two types of features including histogram and CNN are exploited.', 'Under an identical problem setting as CycleGAN, without additional manual inputs and only at a small training-time cost, HarmonicGAN demonstrates a significant qualitative and quantitative improvement over the state of the art, as well as improved interpretability.', 'We show experimental results in a number of applications including medical imaging, object transfiguration, and semantic labeling.', 'We outperform the competing methods in all tasks, and for a medical imaging task in particular our method turns CycleGAN from a failure to a success, halving the mean-squared error, and generating images that radiologists prefer over competing methods in 95% of cases.']
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S1M6Z2Cctm
['Smooth regularization over sample graph for unpaired image-to-image translation results in significantly improved consistency']
The recent direction of unpaired image-to-image translation is on one hand very exciting as it alleviates the big burden in obtaining label-intensive pixel-to-pixel supervision, but it is on the other hand not fully satisfactory due to the presence of artifacts and degenerated transformations., In this paper, we take a manifold view of the problem by introducing a smoothness term over the sample graph to attain harmonic functions to enforce consistent mappings during the translation., We develop HarmonicGAN to learn bi-directional translations between the source and the target domains., With the help of similarity-consistency, the inherent self-consistency property of samples can be maintained., Distance metrics defined on two types of features including histogram and CNN are exploited., Under an identical problem setting as CycleGAN, without additional manual inputs and only at a small training-time cost, HarmonicGAN demonstrates a significant qualitative and quantitative improvement over the state of the art, as well as improved interpretability., We show experimental results in a number of applications including medical imaging, object transfiguration, and semantic labeling., We outperform the competing methods in all tasks, and for a medical imaging task in particular our method turns CycleGAN from a failure to a success, halving the mean-squared error, and generating images that radiologists prefer over competing methods in 95% of cases.
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['Multiview stereo aims to reconstruct scene depth from images acquired by a camera under arbitrary motion.', 'Recent methods address this problem through deep learning, which can utilize semantic cues to deal with challenges such as textureless and reflective regions.', 'In this paper, we present a convolutional neural network called DPSNet (Deep Plane Sweep Network) whose design is inspired by best practices of traditional geometry-based approaches.', 'Rather than directly estimating depth and/or optical flow correspondence from image pairs as done in many previous deep learning methods, DPSNet takes a plane sweep approach that involves building a cost volume from deep features using the plane sweep algorithm, regularizing the cost volume via a context-aware cost aggregation, and regressing the depth map from the cost volume.', 'The cost volume is constructed using a differentiable warping process that allows for end-to-end training of the network.', 'Through the effective incorporation of conventional multiview stereo concepts within a deep learning framework, DPSNet achieves state-of-the-art reconstruction results on a variety of challenging datasets.']
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['A convolution neural network for multi-view stereo matching whose design is inspired by best practices of traditional geometry-based approaches']
Multiview stereo aims to reconstruct scene depth from images acquired by a camera under arbitrary motion., Recent methods address this problem through deep learning, which can utilize semantic cues to deal with challenges such as textureless and reflective regions., In this paper, we present a convolutional neural network called DPSNet (Deep Plane Sweep Network) whose design is inspired by best practices of traditional geometry-based approaches., Rather than directly estimating depth and/or optical flow correspondence from image pairs as done in many previous deep learning methods, DPSNet takes a plane sweep approach that involves building a cost volume from deep features using the plane sweep algorithm, regularizing the cost volume via a context-aware cost aggregation, and regressing the depth map from the cost volume., The cost volume is constructed using a differentiable warping process that allows for end-to-end training of the network., Through the effective incorporation of conventional multiview stereo concepts within a deep learning framework, DPSNet achieves state-of-the-art reconstruction results on a variety of challenging datasets.
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['The ability to design biological structures such as DNA or proteins would have considerable medical and industrial impact.', 'Doing so presents a challenging black-box optimization problem characterized by the large-batch, low round setting due to the need for labor-intensive wet lab evaluations.', 'In response, we propose using reinforcement learning (RL) based on proximal-policy optimization (PPO) for biological sequence design.', 'RL provides a flexible framework for optimization generative sequence models to achieve specific criteria, such as diversity among the high-quality sequences discovered.', 'We propose a model-based variant of PPO, DyNA-PPO, to improve sample efficiency, where the policy for a new round is trained offline using a simulator fit on functional measurements from prior rounds.', 'To accommodate the growing number of observations across rounds, the simulator model is automatically selected at each round from a pool of diverse models of varying capacity. ', 'On the tasks of designing DNA transcription factor binding sites, designing antimicrobial proteins, and optimizing the energy of Ising models based on protein structure, we find that DyNA-PPO performs significantly better than existing methods in settings in which modeling is feasible, while still not performing worse in situations in which a reliable model cannot be learned.']
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HklxbgBKvr
['We augment model-free policy learning with a sequence-level surrogate reward functions and count-based visitation bonus and demonstrate effectiveness in the large batch, low-round regime seen in designing DNA and protein sequences.']
The ability to design biological structures such as DNA or proteins would have considerable medical and industrial impact., Doing so presents a challenging black-box optimization problem characterized by the large-batch, low round setting due to the need for labor-intensive wet lab evaluations., In response, we propose using reinforcement learning (RL) based on proximal-policy optimization (PPO) for biological sequence design., RL provides a flexible framework for optimization generative sequence models to achieve specific criteria, such as diversity among the high-quality sequences discovered., We propose a model-based variant of PPO, DyNA-PPO, to improve sample efficiency, where the policy for a new round is trained offline using a simulator fit on functional measurements from prior rounds., To accommodate the growing number of observations across rounds, the simulator model is automatically selected at each round from a pool of diverse models of varying capacity. , On the tasks of designing DNA transcription factor binding sites, designing antimicrobial proteins, and optimizing the energy of Ising models based on protein structure, we find that DyNA-PPO performs significantly better than existing methods in settings in which modeling is feasible, while still not performing worse in situations in which a reliable model cannot be learned.
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['Achieving machine intelligence requires a smooth integration of perception and reasoning, yet models developed to date tend to specialize in one or the other; sophisticated manipulation of symbols acquired from rich perceptual spaces has so far proved elusive.', 'Consider a visual arithmetic task, where the goal is to carry out simple arithmetical algorithms on digits presented under natural conditions (e.g. hand-written, placed randomly).', 'We propose a two-tiered architecture for tackling this kind of problem.', 'The lower tier consists of a heterogeneous collection of information processing modules, which can include pre-trained deep neural networks for locating and extracting characters from the image, as well as modules performing symbolic transformations on the representations extracted by perception.', 'The higher tier consists of a controller, trained using reinforcement learning, which coordinates the modules in order to solve the high-level task.', 'For instance, the controller may learn in what contexts to execute the perceptual networks and what symbolic transformations to apply to their outputs.', 'The resulting model is able to solve a variety of tasks in the visual arithmetic domain,and has several advantages over standard, architecturally homogeneous feedforward networks including improved sample efficiency.']
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H1kMMmb0-
['We use reinforcement learning to train an agent to solve a set of visual arithmetic tasks using provided pre-trained perceptual modules and transformations of internal representations created by those modules.']
Achieving machine intelligence requires a smooth integration of perception and reasoning, yet models developed to date tend to specialize in one or the other; sophisticated manipulation of symbols acquired from rich perceptual spaces has so far proved elusive., Consider a visual arithmetic task, where the goal is to carry out simple arithmetical algorithms on digits presented under natural conditions (e.g. hand-written, placed randomly)., We propose a two-tiered architecture for tackling this kind of problem., The lower tier consists of a heterogeneous collection of information processing modules, which can include pre-trained deep neural networks for locating and extracting characters from the image, as well as modules performing symbolic transformations on the representations extracted by perception., The higher tier consists of a controller, trained using reinforcement learning, which coordinates the modules in order to solve the high-level task., For instance, the controller may learn in what contexts to execute the perceptual networks and what symbolic transformations to apply to their outputs., The resulting model is able to solve a variety of tasks in the visual arithmetic domain,and has several advantages over standard, architecturally homogeneous feedforward networks including improved sample efficiency.
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['Animals develop novel skills not only through the interaction with the environment but also from the influence of the others.', 'In this work we model the social influence into the scheme of reinforcement learning, enabling the agents to learn both from the environment and from their peers.', 'Specifically, we first define a metric to measure the distance between policies then quantitatively derive the definition of uniqueness.', 'Unlike previous precarious joint optimization approaches, the social uniqueness motivation in our work is imposed as a constraint to encourage the agent to learn a policy different from the existing agents while still solve the primal task.', 'The resulting algorithm, namely Interior Policy Differentiation (IPD), brings about performance improvement as well as a collection of policies that solve a given task with distinct behaviors']
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SJeQi1HKDH
['A new RL algorithm called Interior Policy Differentiation is proposed to learn a collection of diverse policies for a given primal task.']
Animals develop novel skills not only through the interaction with the environment but also from the influence of the others., In this work we model the social influence into the scheme of reinforcement learning, enabling the agents to learn both from the environment and from their peers., Specifically, we first define a metric to measure the distance between policies then quantitatively derive the definition of uniqueness., Unlike previous precarious joint optimization approaches, the social uniqueness motivation in our work is imposed as a constraint to encourage the agent to learn a policy different from the existing agents while still solve the primal task., The resulting algorithm, namely Interior Policy Differentiation (IPD), brings about performance improvement as well as a collection of policies that solve a given task with distinct behaviors
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['Generative adversarial networks (GANs) have been extremely effective in approximating complex distributions of high-dimensional, input data samples, and substantial progress has been made in understanding and improving GAN performance in terms of both theory and application. \n', 'However, we currently lack quantitative methods for model assessment.', 'Because of this, while many GAN variants being proposed, we have relatively little understanding of their relative abilities.', 'In this paper, we evaluate the performance of various types of GANs using divergence and distance functions typically used only for training.', 'We observe consistency across the various proposed metrics and, interestingly, the test-time metrics do not favour networks that use the same training-time criterion.', 'We also compare the proposed metrics to human perceptual scores.']
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SJQHjzZ0-
['An empirical evaluation on generative adversarial networks']
Generative adversarial networks (GANs) have been extremely effective in approximating complex distributions of high-dimensional, input data samples, and substantial progress has been made in understanding and improving GAN performance in terms of both theory and application. , However, we currently lack quantitative methods for model assessment., Because of this, while many GAN variants being proposed, we have relatively little understanding of their relative abilities., In this paper, we evaluate the performance of various types of GANs using divergence and distance functions typically used only for training., We observe consistency across the various proposed metrics and, interestingly, the test-time metrics do not favour networks that use the same training-time criterion., We also compare the proposed metrics to human perceptual scores.
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['Knowledge bases (KB) are often represented as a collection of facts in the form (HEAD, PREDICATE, TAIL), where HEAD and TAIL are entities while PREDICATE is a binary relationship that links the two.', 'It is a well-known fact that knowledge bases are far from complete, and hence the plethora of research on KB completion methods, specifically on link prediction.', 'However, though frequently ignored, these repositories also contain numerical facts.', 'Numerical facts link entities to numerical values via numerical predicates; e.g., (PARIS, LATITUDE, 48.8).', 'Likewise, numerical facts also suffer from the incompleteness problem.', 'To address this issue, we introduce the numerical attribute prediction problem.', 'This problem involves a new type of query where the relationship is a numerical predicate.', 'Consequently, and contrary to link prediction, the answer to this query is a numerical value.', 'We argue that the numerical values associated with entities explain, to some extent, the relational structure of the knowledge base.', 'Therefore, we leverage knowledge base embedding methods to learn representations that are useful predictors for the numerical attributes.', 'An extensive set of experiments on benchmark versions of FREEBASE and YAGO show that our approaches largely outperform sensible baselines.', 'We make the datasets available under a permissive BSD-3 license.']
[0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0]
[0.19512194395065308, 0.1666666567325592, 0.0952380895614624, 0.2222222238779068, 0.09999999403953552, 0.1818181723356247, 0.1599999964237213, 0.07999999821186066, 0.48275861144065857, 0.13793103396892548, 0.06666666269302368, 0.0]
BJlh0x9ppQ
['Prediction of numerical attribute values associated with entities in knowledge bases.']
Knowledge bases (KB) are often represented as a collection of facts in the form (HEAD, PREDICATE, TAIL), where HEAD and TAIL are entities while PREDICATE is a binary relationship that links the two., It is a well-known fact that knowledge bases are far from complete, and hence the plethora of research on KB completion methods, specifically on link prediction., However, though frequently ignored, these repositories also contain numerical facts., Numerical facts link entities to numerical values via numerical predicates; e.g., (PARIS, LATITUDE, 48.8)., Likewise, numerical facts also suffer from the incompleteness problem., To address this issue, we introduce the numerical attribute prediction problem., This problem involves a new type of query where the relationship is a numerical predicate., Consequently, and contrary to link prediction, the answer to this query is a numerical value., We argue that the numerical values associated with entities explain, to some extent, the relational structure of the knowledge base., Therefore, we leverage knowledge base embedding methods to learn representations that are useful predictors for the numerical attributes., An extensive set of experiments on benchmark versions of FREEBASE and YAGO show that our approaches largely outperform sensible baselines., We make the datasets available under a permissive BSD-3 license.
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['We propose procedures for evaluating and strengthening contextual embedding alignment and show that they are useful in analyzing and improving multilingual BERT.', 'In particular, after our proposed alignment procedure, BERT exhibits significantly improved zero-shot performance on XNLI compared to the base model, remarkably matching pseudo-fully-supervised translate-train models for Bulgarian and Greek.', 'Further, to measure the degree of alignment, we introduce a contextual version of word retrieval and show that it correlates well with downstream zero-shot transfer.', 'Using this word retrieval task, we also analyze BERT and find that it exhibits systematic deficiencies, e.g. worse alignment for open-class parts-of-speech and word pairs written in different scripts, that are corrected by the alignment procedure.', 'These results support contextual alignment as a useful concept for understanding large multilingual pre-trained models.']
[1, 0, 0, 0, 0]
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r1xCMyBtPS
["We propose procedures for evaluating and strengthening contextual embedding alignment and show that they both improve multilingual BERT's zero-shot XNLI transfer and provide useful insights into the model."]
We propose procedures for evaluating and strengthening contextual embedding alignment and show that they are useful in analyzing and improving multilingual BERT., In particular, after our proposed alignment procedure, BERT exhibits significantly improved zero-shot performance on XNLI compared to the base model, remarkably matching pseudo-fully-supervised translate-train models for Bulgarian and Greek., Further, to measure the degree of alignment, we introduce a contextual version of word retrieval and show that it correlates well with downstream zero-shot transfer., Using this word retrieval task, we also analyze BERT and find that it exhibits systematic deficiencies, e.g. worse alignment for open-class parts-of-speech and word pairs written in different scripts, that are corrected by the alignment procedure., These results support contextual alignment as a useful concept for understanding large multilingual pre-trained models.
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['Neural networks have reached outstanding performance for solving various ill-posed inverse problems in imaging.', 'However, drawbacks of end-to-end learning approaches in comparison to classical variational methods are the requirement of expensive retraining for even slightly different problem statements and the lack of provable error bounds during inference.', 'Recent works tackled the first problem by using networks trained for Gaussian image denoising as generic plug-and-play regularizers in energy minimization algorithms.', 'Even though this obtains state-of-the-art results on many tasks, heavy restrictions on the network architecture have to be made if provable convergence of the underlying fixed point iteration is a requirement.', 'More recent work has proposed to train networks to output descent directions with respect to a given energy function with a provable guarantee of convergence to a minimizer of that energy.', 'However, each problem and energy requires the training of a separate network.\n', 'In this paper we consider the combination of both approaches by projecting the outputs of a plug-and-play denoising network onto the cone of descent directions to a given energy.', 'This way, a single pre-trained network can be used for a wide variety of reconstruction tasks.', 'Our results show improvements compared to classical energy minimization methods while still having provable convergence guarantees.']
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SJxRjQncLH
['We use neural networks trained for image denoising as plug-and-play priors in energy minimization algorithms for image reconstruction problems with provable convergence.']
Neural networks have reached outstanding performance for solving various ill-posed inverse problems in imaging., However, drawbacks of end-to-end learning approaches in comparison to classical variational methods are the requirement of expensive retraining for even slightly different problem statements and the lack of provable error bounds during inference., Recent works tackled the first problem by using networks trained for Gaussian image denoising as generic plug-and-play regularizers in energy minimization algorithms., Even though this obtains state-of-the-art results on many tasks, heavy restrictions on the network architecture have to be made if provable convergence of the underlying fixed point iteration is a requirement., More recent work has proposed to train networks to output descent directions with respect to a given energy function with a provable guarantee of convergence to a minimizer of that energy., However, each problem and energy requires the training of a separate network. , In this paper we consider the combination of both approaches by projecting the outputs of a plug-and-play denoising network onto the cone of descent directions to a given energy., This way, a single pre-trained network can be used for a wide variety of reconstruction tasks., Our results show improvements compared to classical energy minimization methods while still having provable convergence guarantees.
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['Knowledge graph embedding research has overlooked the problem of probability calibration.', 'We show popular embedding models are indeed uncalibrated.', 'That means probability estimates associated to predicted triples are unreliable.', 'We present a novel method to calibrate a model when ground truth negatives are not available, which is the usual case in knowledge graphs.', 'We propose to use Platt scaling and isotonic regression alongside our method.', 'Experiments on three datasets with ground truth negatives show our contribution leads to well calibrated models when compared to the gold standard of using negatives.', 'We get significantly better results than the uncalibrated models from all calibration methods.', 'We show isotonic regression offers the best the performance overall, not without trade-offs.', 'We also show that calibrated models reach state-of-the-art accuracy without the need to define relation-specific decision thresholds.']
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S1g8K1BFwS
['We propose a novel method to calibrate knowledge graph embedding models without the need of negative examples.']
Knowledge graph embedding research has overlooked the problem of probability calibration., We show popular embedding models are indeed uncalibrated., That means probability estimates associated to predicted triples are unreliable., We present a novel method to calibrate a model when ground truth negatives are not available, which is the usual case in knowledge graphs., We propose to use Platt scaling and isotonic regression alongside our method., Experiments on three datasets with ground truth negatives show our contribution leads to well calibrated models when compared to the gold standard of using negatives., We get significantly better results than the uncalibrated models from all calibration methods., We show isotonic regression offers the best the performance overall, not without trade-offs., We also show that calibrated models reach state-of-the-art accuracy without the need to define relation-specific decision thresholds.
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['As an emerging topic in face recognition, designing margin-based loss functions can increase the feature margin between different classes for enhanced discriminability.', 'More recently, absorbing the idea of mining-based strategies is adopted to emphasize the misclassified samples and achieve promising results.', 'However, during the entire training process, the prior methods either do not explicitly emphasize the sample based on its importance that renders the hard samples not fully exploited or explicitly emphasize the effects of semi-hard/hard samples even at the early training stage that may lead to convergence issues.', 'In this work, we propose a novel Adaptive Curriculum Learning loss (CurricularFace) that embeds the idea of curriculum learning into the loss function to achieve a novel training strategy for deep face recognition, which mainly addresses easy samples in the early training stage and hard ones in the later stage.', 'Specifically, our CurricularFace adaptively adjusts the relative importance of easy and hard samples during different training stages.', 'In each stage, different samples are assigned with different importance according to their corresponding difficultness.', 'Extensive experimental results on popular benchmarks demonstrate the superiority of our CurricularFace over the state-of-the-art competitors.', 'Code will be available upon publication.']
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B1eksh4KvH
['A novel Adaptive Curriculum Learning loss for deep face recognition']
As an emerging topic in face recognition, designing margin-based loss functions can increase the feature margin between different classes for enhanced discriminability., More recently, absorbing the idea of mining-based strategies is adopted to emphasize the misclassified samples and achieve promising results., However, during the entire training process, the prior methods either do not explicitly emphasize the sample based on its importance that renders the hard samples not fully exploited or explicitly emphasize the effects of semi-hard/hard samples even at the early training stage that may lead to convergence issues., In this work, we propose a novel Adaptive Curriculum Learning loss (CurricularFace) that embeds the idea of curriculum learning into the loss function to achieve a novel training strategy for deep face recognition, which mainly addresses easy samples in the early training stage and hard ones in the later stage., Specifically, our CurricularFace adaptively adjusts the relative importance of easy and hard samples during different training stages., In each stage, different samples are assigned with different importance according to their corresponding difficultness., Extensive experimental results on popular benchmarks demonstrate the superiority of our CurricularFace over the state-of-the-art competitors., Code will be available upon publication.
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['Adversarial examples are perturbed inputs designed to fool machine learning models.', 'Adversarial training injects such examples into training data to increase robustness.', "To scale this technique to large datasets, perturbations are crafted using fast single-step methods that maximize a linear approximation of the model's loss.\n", 'We show that this form of adversarial training converges to a degenerate global minimum, wherein small curvature artifacts near the data points obfuscate a linear approximation of the loss.', 'The model thus learns to generate weak perturbations, rather than defend against strong ones.', 'As a result, we find that adversarial training remains vulnerable to black-box attacks, where we transfer perturbations computed on undefended models, as well as to a powerful novel single-step attack that escapes the non-smooth vicinity of the input data via a small random step.\n', 'We further introduce Ensemble Adversarial Training, a technique that augments training data with perturbations transferred from other models.', 'On ImageNet, Ensemble Adversarial Training yields models with strong robustness to black-box attacks.', 'In particular, our most robust model won the first round of the NIPS 2017 competition on Defenses against Adversarial Attacks.']
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rkZvSe-RZ
['Adversarial training with single-step methods overfits, and remains vulnerable to simple black-box and white-box attacks. We show that including adversarial examples from multiple sources helps defend against black-box attacks.']
Adversarial examples are perturbed inputs designed to fool machine learning models., Adversarial training injects such examples into training data to increase robustness., To scale this technique to large datasets, perturbations are crafted using fast single-step methods that maximize a linear approximation of the model's loss. , We show that this form of adversarial training converges to a degenerate global minimum, wherein small curvature artifacts near the data points obfuscate a linear approximation of the loss., The model thus learns to generate weak perturbations, rather than defend against strong ones., As a result, we find that adversarial training remains vulnerable to black-box attacks, where we transfer perturbations computed on undefended models, as well as to a powerful novel single-step attack that escapes the non-smooth vicinity of the input data via a small random step. , We further introduce Ensemble Adversarial Training, a technique that augments training data with perturbations transferred from other models., On ImageNet, Ensemble Adversarial Training yields models with strong robustness to black-box attacks., In particular, our most robust model won the first round of the NIPS 2017 competition on Defenses against Adversarial Attacks.
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['An adversarial feature learning (AFL) is a powerful framework to learn representations invariant to a nuisance attribute, which uses an adversarial game between a feature extractor and a categorical attribute classifier.', 'It theoretically sounds in term of it maximize conditional entropy between attribute and representation.', 'However, as shown in this paper, the AFL often causes unstable behavior that slows down the convergence.', 'We propose an {\\em attribute perception matching} as an alternative approach, based on the reformulation of conditional entropy maximization as {\\em pair-wise distribution matching}. Although the naive approach for realizing the pair-wise distribution matching requires the significantly large number of parameters, the proposed method requires the same number of parameters with AFL but has a better convergence property.', 'Experiments on both toy and real-world dataset prove that our proposed method converges to better invariant representation significantly faster than AFL. ']
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r1ew74mluN
['This paper proposes a new approach to incorporating desired invariance to representations learning, based on the observations that the current state-of-the-art AFL has practical issues.']
An adversarial feature learning (AFL) is a powerful framework to learn representations invariant to a nuisance attribute, which uses an adversarial game between a feature extractor and a categorical attribute classifier., It theoretically sounds in term of it maximize conditional entropy between attribute and representation., However, as shown in this paper, the AFL often causes unstable behavior that slows down the convergence., We propose an {\em attribute perception matching} as an alternative approach, based on the reformulation of conditional entropy maximization as {\em pair-wise distribution matching}. Although the naive approach for realizing the pair-wise distribution matching requires the significantly large number of parameters, the proposed method requires the same number of parameters with AFL but has a better convergence property., Experiments on both toy and real-world dataset prove that our proposed method converges to better invariant representation significantly faster than AFL.
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['We study the properties of common loss surfaces through their Hessian matrix.', 'In particular, in the context of deep learning, we empirically show that the spectrum of the Hessian is composed of two parts: (1) the bulk centered near zero, (2) and outliers away from the bulk.', 'We present numerical evidence and mathematical justifications to the following conjectures laid out by Sagun et.', 'al. (2016): Fixing data, increasing the number of parameters merely scales the bulk of the spectrum; fixing the dimension and changing the data (for instance adding more clusters or making the data less separable) only affects the outliers.', 'We believe that our observations have striking implications for non-convex optimization in high dimensions.', 'First, the *flatness* of such landscapes (which can be measured by the singularity of the Hessian) implies that classical notions of basins of attraction may be quite misleading.', 'And that the discussion of wide/narrow basins may be in need of a new perspective around over-parametrization and redundancy that are able to create *large* connected components at the bottom of the landscape.', 'Second, the dependence of a small number of large eigenvalues to the data distribution can be linked to the spectrum of the covariance matrix of gradients of model outputs.', 'With this in mind, we may reevaluate the connections within the data-architecture-algorithm framework of a model, hoping that it would shed light on the geometry of high-dimensional and non-convex spaces in modern applications.', 'In particular, we present a case that links the two observations: small and large batch gradient descent appear to converge to different basins of attraction but we show that they are in fact connected through their flat region and so belong to the same basin.']
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rJrTwxbCb
['The loss surface is *very* degenerate, and there are no barriers between large batch and small batch solutions.']
We study the properties of common loss surfaces through their Hessian matrix., In particular, in the context of deep learning, we empirically show that the spectrum of the Hessian is composed of two parts: (1) the bulk centered near zero, (2) and outliers away from the bulk., We present numerical evidence and mathematical justifications to the following conjectures laid out by Sagun et., al. (2016): Fixing data, increasing the number of parameters merely scales the bulk of the spectrum; fixing the dimension and changing the data (for instance adding more clusters or making the data less separable) only affects the outliers., We believe that our observations have striking implications for non-convex optimization in high dimensions., First, the *flatness* of such landscapes (which can be measured by the singularity of the Hessian) implies that classical notions of basins of attraction may be quite misleading., And that the discussion of wide/narrow basins may be in need of a new perspective around over-parametrization and redundancy that are able to create *large* connected components at the bottom of the landscape., Second, the dependence of a small number of large eigenvalues to the data distribution can be linked to the spectrum of the covariance matrix of gradients of model outputs., With this in mind, we may reevaluate the connections within the data-architecture-algorithm framework of a model, hoping that it would shed light on the geometry of high-dimensional and non-convex spaces in modern applications., In particular, we present a case that links the two observations: small and large batch gradient descent appear to converge to different basins of attraction but we show that they are in fact connected through their flat region and so belong to the same basin.
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['The allocation of computation resources in the backbone is a crucial issue in object detection.', 'However, classification allocation pattern is usually adopted directly to object detector, which is proved to be sub-optimal.', 'In order to reallocate the engaged computation resources in a more efficient way, we present CR-NAS (Computation Reallocation Neural Architecture Search) that can learn computation reallocation strategies across different feature resolution and spatial position diectly on the target detection dataset.', 'A two-level reallocation space is proposed for both stage and spatial reallocation.', 'A novel hierarchical search procedure is adopted to cope with the complex search space.', 'We apply CR-NAS to multiple backbones and achieve consistent improvements.', 'Our CR-ResNet50 and CR-MobileNetV2 outperforms the baseline by 1.9% and 1.7% COCO AP respectively without any additional computation budget.', 'The models discovered by CR-NAS can be equiped to other powerful detection neck/head and be easily transferred to other dataset, e.g. PASCAL VOC, and other vision tasks, e.g. instance segmentation.', 'Our CR-NAS can be used as a plugin to improve the performance of various networks, which is demanding.']
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SkxLFaNKwB
['We propose CR-NAS to reallocate engaged computation resources in different resolution and spatial position.']
The allocation of computation resources in the backbone is a crucial issue in object detection., However, classification allocation pattern is usually adopted directly to object detector, which is proved to be sub-optimal., In order to reallocate the engaged computation resources in a more efficient way, we present CR-NAS (Computation Reallocation Neural Architecture Search) that can learn computation reallocation strategies across different feature resolution and spatial position diectly on the target detection dataset., A two-level reallocation space is proposed for both stage and spatial reallocation., A novel hierarchical search procedure is adopted to cope with the complex search space., We apply CR-NAS to multiple backbones and achieve consistent improvements., Our CR-ResNet50 and CR-MobileNetV2 outperforms the baseline by 1.9% and 1.7% COCO AP respectively without any additional computation budget., The models discovered by CR-NAS can be equiped to other powerful detection neck/head and be easily transferred to other dataset, e.g. PASCAL VOC, and other vision tasks, e.g. instance segmentation., Our CR-NAS can be used as a plugin to improve the performance of various networks, which is demanding.
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['Uncertainty is a very important feature of the intelligence and helps the brain become a flexible, creative and powerful intelligent system.', 'The crossbar-based neuromorphic computing chips, in which the computing is mainly performed by analog circuits, have the uncertainty and can be used to imitate the brain.', 'However, most of the current deep neural networks have not taken the uncertainty of the neuromorphic computing chip into consideration.', 'Therefore, their performances on the neuromorphic computing chips are not as good as on the original platforms (CPUs/GPUs).', 'In this work, we proposed the uncertainty adaptation training scheme (UATS) that tells the uncertainty to the neural network in the training process.', 'The experimental results show that the neural networks can achieve comparable inference performances on the uncertain neuromorphic computing chip compared to the results on the original platforms, and much better than the performances without this training scheme.']
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[0.0, 0.19999998807907104, 0.23529411852359772, 0.25, 0.17142856121063232, 0.2978723347187042]
Byekm0VtwS
['A training method that can make deep learning algorithms work better on neuromorphic computing chips with uncertainty']
Uncertainty is a very important feature of the intelligence and helps the brain become a flexible, creative and powerful intelligent system., The crossbar-based neuromorphic computing chips, in which the computing is mainly performed by analog circuits, have the uncertainty and can be used to imitate the brain., However, most of the current deep neural networks have not taken the uncertainty of the neuromorphic computing chip into consideration., Therefore, their performances on the neuromorphic computing chips are not as good as on the original platforms (CPUs/GPUs)., In this work, we proposed the uncertainty adaptation training scheme (UATS) that tells the uncertainty to the neural network in the training process., The experimental results show that the neural networks can achieve comparable inference performances on the uncertain neuromorphic computing chip compared to the results on the original platforms, and much better than the performances without this training scheme.
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["An important property of image classification systems in the real world is that they both accurately classify objects from target classes (``knowns'') and safely reject unknown objects (``unknowns'') that belong to classes not present in the training data.", 'Unfortunately, although the strong generalization ability of existing CNNs ensures their accuracy when classifying known objects, it also causes them to often assign an unknown to a target class with high confidence.', 'As a result, simply using low-confidence detections as a way to detect unknowns does not work well.', 'In this work, we propose an Unknown-aware Deep Neural Network (UDN for short) to solve this challenging problem.', 'The key idea of UDN is to enhance existing CNNs to support a product operation that models the product relationship among the features produced by convolutional layers.', 'This way, missing a single key feature of a target class will greatly reduce the probability of assigning an object to this class.', 'UDN uses a learned ensemble of these product operations, which allows it to balance the contradictory requirements of accurately classifying known objects and correctly rejecting unknowns.', 'To further improve the performance of UDN at detecting unknowns, we propose an information-theoretic regularization strategy that incorporates the objective of rejecting unknowns into the learning process of UDN.', 'We experiment on benchmark image datasets including MNIST, CIFAR-10, CIFAR-100, and SVHN, adding unknowns by injecting one dataset into another.', 'Our results demonstrate that UDN significantly outperforms state-of-the-art methods at rejecting unknowns by 25 percentage points improvement in accuracy, while still preserving the classification accuracy.']
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rkguLC4tPB
['A CNN architecture that can effective rejects the unknowns in test objects']
An important property of image classification systems in the real world is that they both accurately classify objects from target classes (``knowns'') and safely reject unknown objects (``unknowns'') that belong to classes not present in the training data., Unfortunately, although the strong generalization ability of existing CNNs ensures their accuracy when classifying known objects, it also causes them to often assign an unknown to a target class with high confidence., As a result, simply using low-confidence detections as a way to detect unknowns does not work well., In this work, we propose an Unknown-aware Deep Neural Network (UDN for short) to solve this challenging problem., The key idea of UDN is to enhance existing CNNs to support a product operation that models the product relationship among the features produced by convolutional layers., This way, missing a single key feature of a target class will greatly reduce the probability of assigning an object to this class., UDN uses a learned ensemble of these product operations, which allows it to balance the contradictory requirements of accurately classifying known objects and correctly rejecting unknowns., To further improve the performance of UDN at detecting unknowns, we propose an information-theoretic regularization strategy that incorporates the objective of rejecting unknowns into the learning process of UDN., We experiment on benchmark image datasets including MNIST, CIFAR-10, CIFAR-100, and SVHN, adding unknowns by injecting one dataset into another., Our results demonstrate that UDN significantly outperforms state-of-the-art methods at rejecting unknowns by 25 percentage points improvement in accuracy, while still preserving the classification accuracy.
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['Multivariate time series with missing values are common in areas such as healthcare and finance, and have grown in number and complexity over the years.', 'This raises the question whether deep learning methodologies can outperform classical data imputation methods in this domain.', 'However, naive applications of deep learning fall short in giving reliable confidence estimates and lack interpretability.', 'We propose a new deep sequential latent variable model for dimensionality reduction and data imputation.', 'Our modeling assumption is simple and interpretable: the high dimensional time series has a lower-dimensional representation which evolves smoothly in time according to a Gaussian process.', 'The non-linear dimensionality reduction in the presence of missing data is achieved using a VAE approach with a novel structured variational approximation.', 'We demonstrate that our approach outperforms several classical and deep learning-based data imputation methods on high-dimensional data from the domains of computer vision and healthcare, while additionally improving the smoothness of the imputations and providing interpretable uncertainty estimates.']
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H1xXYy3VKr
['We perform amortized variational inference on a latent Gaussian process model to achieve superior imputation performance on multivariate time series with missing data.']
Multivariate time series with missing values are common in areas such as healthcare and finance, and have grown in number and complexity over the years., This raises the question whether deep learning methodologies can outperform classical data imputation methods in this domain., However, naive applications of deep learning fall short in giving reliable confidence estimates and lack interpretability., We propose a new deep sequential latent variable model for dimensionality reduction and data imputation., Our modeling assumption is simple and interpretable: the high dimensional time series has a lower-dimensional representation which evolves smoothly in time according to a Gaussian process., The non-linear dimensionality reduction in the presence of missing data is achieved using a VAE approach with a novel structured variational approximation., We demonstrate that our approach outperforms several classical and deep learning-based data imputation methods on high-dimensional data from the domains of computer vision and healthcare, while additionally improving the smoothness of the imputations and providing interpretable uncertainty estimates.
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['In practice it is often found that large over-parameterized neural networks generalize better than their smaller counterparts, an observation that appears to conflict with classical notions of function complexity, which typically favor smaller models.', 'In this work, we investigate this tension between complexity and generalization through an extensive empirical exploration of two natural metrics of complexity related to sensitivity to input perturbations.', 'Our experiments survey thousands of models with different architectures, optimizers, and other hyper-parameters, as well as four different image classification datasets.\n\n', 'We find that trained neural networks are more robust to input perturbations in the vicinity of the training data manifold, as measured by the input-output Jacobian of the network, and that this correlates well with generalization.', 'We further establish that factors associated with poor generalization -- such as full-batch training or using random labels -- correspond to higher sensitivity, while factors associated with good generalization -- such as data augmentation and ReLU non-linearities -- give rise to more robust functions.', 'Finally, we demonstrate how the input-output Jacobian norm can be predictive of generalization at the level of individual test points.']
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HJC2SzZCW
['We perform massive experimental studies characterizing the relationships between Jacobian norms, linear regions, and generalization.']
In practice it is often found that large over-parameterized neural networks generalize better than their smaller counterparts, an observation that appears to conflict with classical notions of function complexity, which typically favor smaller models., In this work, we investigate this tension between complexity and generalization through an extensive empirical exploration of two natural metrics of complexity related to sensitivity to input perturbations., Our experiments survey thousands of models with different architectures, optimizers, and other hyper-parameters, as well as four different image classification datasets. , We find that trained neural networks are more robust to input perturbations in the vicinity of the training data manifold, as measured by the input-output Jacobian of the network, and that this correlates well with generalization., We further establish that factors associated with poor generalization -- such as full-batch training or using random labels -- correspond to higher sensitivity, while factors associated with good generalization -- such as data augmentation and ReLU non-linearities -- give rise to more robust functions., Finally, we demonstrate how the input-output Jacobian norm can be predictive of generalization at the level of individual test points.
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['Deep reinforcement learning (RL) methods generally engage in exploratory behavior through noise injection in the action space.', "An alternative is to add noise directly to the agent's parameters, which can lead to more consistent exploration and a richer set of behaviors.", 'Methods such as evolutionary strategies use parameter perturbations, but discard all temporal structure in the process and require significantly more samples.', 'Combining parameter noise with traditional RL methods allows to combine the best of both worlds.', 'We demonstrate that both off- and on-policy methods benefit from this approach through experimental comparison of DQN, DDPG, and TRPO on high-dimensional discrete action environments as well as continuous control tasks.']
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ByBAl2eAZ
['Parameter space noise allows reinforcement learning algorithms to explore by perturbing parameters instead of actions, often leading to significantly improved exploration performance.']
Deep reinforcement learning (RL) methods generally engage in exploratory behavior through noise injection in the action space., An alternative is to add noise directly to the agent's parameters, which can lead to more consistent exploration and a richer set of behaviors., Methods such as evolutionary strategies use parameter perturbations, but discard all temporal structure in the process and require significantly more samples., Combining parameter noise with traditional RL methods allows to combine the best of both worlds., We demonstrate that both off- and on-policy methods benefit from this approach through experimental comparison of DQN, DDPG, and TRPO on high-dimensional discrete action environments as well as continuous control tasks.
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['Pre-trained deep neural network language models such as ELMo, GPT, BERT and XLNet have recently achieved state-of-the-art performance on a variety of language understanding tasks.', 'However, their size makes them impractical for a number of scenarios, especially on mobile and edge devices.', "In particular, the input word embedding matrix accounts for a significant proportion of the model's memory footprint, due to the large input vocabulary and embedding dimensions.", 'Knowledge distillation techniques have had success at compressing large neural network models, but they are ineffective at yielding student models with vocabularies different from the original teacher models.', 'We introduce a novel knowledge distillation technique for training a student model with a significantly smaller vocabulary as well as lower embedding and hidden state dimensions.', 'Specifically, we employ a dual-training mechanism that trains the teacher and student models simultaneously to obtain optimal word embeddings for the student vocabulary.', 'We combine this approach with learning shared projection matrices that transfer layer-wise knowledge from the teacher model to the student model.', 'Our method is able to compress the BERT-BASE model by more than 60x, with only a minor drop in downstream task metrics, resulting in a language model with a footprint of under 7MB.', 'Experimental results also demonstrate higher compression efficiency and accuracy when compared with other state-of-the-art compression techniques.']
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S1x6ueSKPr
['We present novel distillation techniques that enable training student models with different vocabularies and compress BERT by 60x with minor performance drop.']
Pre-trained deep neural network language models such as ELMo, GPT, BERT and XLNet have recently achieved state-of-the-art performance on a variety of language understanding tasks., However, their size makes them impractical for a number of scenarios, especially on mobile and edge devices., In particular, the input word embedding matrix accounts for a significant proportion of the model's memory footprint, due to the large input vocabulary and embedding dimensions., Knowledge distillation techniques have had success at compressing large neural network models, but they are ineffective at yielding student models with vocabularies different from the original teacher models., We introduce a novel knowledge distillation technique for training a student model with a significantly smaller vocabulary as well as lower embedding and hidden state dimensions., Specifically, we employ a dual-training mechanism that trains the teacher and student models simultaneously to obtain optimal word embeddings for the student vocabulary., We combine this approach with learning shared projection matrices that transfer layer-wise knowledge from the teacher model to the student model., Our method is able to compress the BERT-BASE model by more than 60x, with only a minor drop in downstream task metrics, resulting in a language model with a footprint of under 7MB., Experimental results also demonstrate higher compression efficiency and accuracy when compared with other state-of-the-art compression techniques.
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['Human reasoning involves recognising common underlying principles across many examples by utilising variables.', 'The by-products of such reasoning are invariants that capture patterns across examples such as "if someone went somewhere then they are there" without mentioning specific people or places.', 'Humans learn what variables are and how to use them at a young age, and the question this paper addresses is whether machines can also learn and use variables solely from examples without requiring human pre-engineering.', 'We propose Unification Networks that incorporate soft unification into neural networks to learn variables and by doing so lift examples into invariants that can then be used to solve a given task.', 'We evaluate our approach on four datasets to demonstrate that learning invariants captures patterns in the data and can improve performance over baselines.']
[0, 1, 0, 0, 0]
[0.1875, 0.4888888895511627, 0.11999999731779099, 0.1249999925494194, 0.0476190410554409]
r1xwA34KDB
['End-to-end learning of invariant representations with variables across examples such as if someone went somewhere then they are there.']
Human reasoning involves recognising common underlying principles across many examples by utilising variables., The by-products of such reasoning are invariants that capture patterns across examples such as "if someone went somewhere then they are there" without mentioning specific people or places., Humans learn what variables are and how to use them at a young age, and the question this paper addresses is whether machines can also learn and use variables solely from examples without requiring human pre-engineering., We propose Unification Networks that incorporate soft unification into neural networks to learn variables and by doing so lift examples into invariants that can then be used to solve a given task., We evaluate our approach on four datasets to demonstrate that learning invariants captures patterns in the data and can improve performance over baselines.
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['We propose a new learning-based approach to solve ill-posed inverse problems in imaging.', 'We address the case where ground truth training samples are rare and the problem is severely ill-posed---both because of the underlying physics and because we can only get few measurements.', 'This setting is common in geophysical imaging and remote sensing.', 'We show that in this case the common approach to directly learn the mapping from the measured data to the reconstruction becomes unstable.', 'Instead, we propose to first learn an ensemble of simpler mappings from the data to projections of the unknown image into random piecewise-constant subspaces.', 'We then combine the projections to form a final reconstruction by solving a deconvolution-like problem.', 'We show experimentally that the proposed method is more robust to measurement noise and corruptions not seen during training than a directly learned inverse.']
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HyGcghRct7
['We solve ill-posed inverse problems with scarce ground truth examples by estimating an ensemble of random projections of the model instead of the model itself.']
We propose a new learning-based approach to solve ill-posed inverse problems in imaging., We address the case where ground truth training samples are rare and the problem is severely ill-posed---both because of the underlying physics and because we can only get few measurements., This setting is common in geophysical imaging and remote sensing., We show that in this case the common approach to directly learn the mapping from the measured data to the reconstruction becomes unstable., Instead, we propose to first learn an ensemble of simpler mappings from the data to projections of the unknown image into random piecewise-constant subspaces., We then combine the projections to form a final reconstruction by solving a deconvolution-like problem., We show experimentally that the proposed method is more robust to measurement noise and corruptions not seen during training than a directly learned inverse.
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['Designing architectures for deep neural networks requires expert knowledge and substantial computation time.', "We propose a technique to accelerate architecture selection by learning an auxiliary HyperNet that generates the weights of a main model conditioned on that model's architecture.", 'By comparing the relative validation performance of networks with HyperNet-generated weights, we can effectively search over a wide range of architectures at the cost of a single training run.', 'To facilitate this search, we develop a flexible mechanism based on memory read-writes that allows us to define a wide range of network connectivity patterns, with ResNet, DenseNet, and FractalNet blocks as special cases.', 'We validate our method (SMASH) on CIFAR-10 and CIFAR-100, STL-10, ModelNet10, and Imagenet32x32, achieving competitive performance with similarly-sized hand-designed networks.']
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rydeCEhs-
['A technique for accelerating neural architecture selection by approximating the weights of each candidate architecture instead of training them individually.']
Designing architectures for deep neural networks requires expert knowledge and substantial computation time., We propose a technique to accelerate architecture selection by learning an auxiliary HyperNet that generates the weights of a main model conditioned on that model's architecture., By comparing the relative validation performance of networks with HyperNet-generated weights, we can effectively search over a wide range of architectures at the cost of a single training run., To facilitate this search, we develop a flexible mechanism based on memory read-writes that allows us to define a wide range of network connectivity patterns, with ResNet, DenseNet, and FractalNet blocks as special cases., We validate our method (SMASH) on CIFAR-10 and CIFAR-100, STL-10, ModelNet10, and Imagenet32x32, achieving competitive performance with similarly-sized hand-designed networks.
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['Textual entailment (or NLI) data has proven useful as pretraining data for tasks requiring language understanding, even when building on an already-pretrained model like RoBERTa.', 'The standard protocol for collecting NLI was not designed for the creation of pretraining data, and it is likely far from ideal for this purpose.', 'With this application in mind we propose four alternative protocols, each aimed at improving either the ease with which annotators can produce sound training examples or the quality and diversity of those examples.', 'Using these alternatives and a simple MNLIbased baseline, we collect and compare five new 9k-example training sets.', 'Our primary results are largely negative, with none of these new methods showing major improvements in transfer learning.', 'However, we make several observations that should inform future work on NLI data, such as that the use of automatically provided seed sentences for inspiration improves the quality of the resulting data on most measures, and all of the interventions we investigated dramatically reduce previously observed issues with annotation artifacts.']
[0, 0, 0, 0, 0, 1]
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rc8gt9r_TTB
['We propose four new ways of collecting NLI data. Some help slightly as pretraining data, all help reduce annotation artifacts.']
Textual entailment (or NLI) data has proven useful as pretraining data for tasks requiring language understanding, even when building on an already-pretrained model like RoBERTa., The standard protocol for collecting NLI was not designed for the creation of pretraining data, and it is likely far from ideal for this purpose., With this application in mind we propose four alternative protocols, each aimed at improving either the ease with which annotators can produce sound training examples or the quality and diversity of those examples., Using these alternatives and a simple MNLIbased baseline, we collect and compare five new 9k-example training sets., Our primary results are largely negative, with none of these new methods showing major improvements in transfer learning., However, we make several observations that should inform future work on NLI data, such as that the use of automatically provided seed sentences for inspiration improves the quality of the resulting data on most measures, and all of the interventions we investigated dramatically reduce previously observed issues with annotation artifacts.
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['Predicting the future in real-world settings, particularly from raw sensory observations such as images, is exceptionally challenging.', 'Real-world events can be stochastic and unpredictable, and the high dimensionality and complexity of natural images requires the predictive model to build an intricate understanding of the natural world.', 'Many existing methods tackle this problem by making simplifying assumptions about the environment.', 'One common assumption is that the outcome is deterministic and there is only one plausible future.', 'This can lead to low-quality predictions in real-world settings with stochastic dynamics.', 'In this paper, we develop a stochastic variational video prediction (SV2P) method that predicts a different possible future for each sample of its latent variables.', 'To the best of our knowledge, our model is the first to provide effective stochastic multi-frame prediction for real-world video.', 'We demonstrate the capability of the proposed method in predicting detailed future frames of videos on multiple real-world datasets, both action-free and action-conditioned.', 'We find that our proposed method produces substantially improved video predictions when compared to the same model without stochasticity, and to other stochastic video prediction methods.', 'Our SV2P implementation will be open sourced upon publication.']
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rk49Mg-CW
['Stochastic variational video prediction in real-world settings.']
Predicting the future in real-world settings, particularly from raw sensory observations such as images, is exceptionally challenging., Real-world events can be stochastic and unpredictable, and the high dimensionality and complexity of natural images requires the predictive model to build an intricate understanding of the natural world., Many existing methods tackle this problem by making simplifying assumptions about the environment., One common assumption is that the outcome is deterministic and there is only one plausible future., This can lead to low-quality predictions in real-world settings with stochastic dynamics., In this paper, we develop a stochastic variational video prediction (SV2P) method that predicts a different possible future for each sample of its latent variables., To the best of our knowledge, our model is the first to provide effective stochastic multi-frame prediction for real-world video., We demonstrate the capability of the proposed method in predicting detailed future frames of videos on multiple real-world datasets, both action-free and action-conditioned., We find that our proposed method produces substantially improved video predictions when compared to the same model without stochasticity, and to other stochastic video prediction methods., Our SV2P implementation will be open sourced upon publication.
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['In multi-agent systems, complex interacting behaviors arise due to the high correlations among agents.', 'However, previous work on modeling multi-agent interactions from demonstrations is primarily constrained by assuming the independence among policies and their reward structures. \n', "In this paper, we cast the multi-agent interactions modeling problem into a multi-agent imitation learning framework with explicit modeling of correlated policies by approximating opponents’ policies, which can recover agents' policies that can regenerate similar interactions.", 'Consequently, we develop a Decentralized Adversarial Imitation Learning algorithm with Correlated policies (CoDAIL), which allows for decentralized training and execution.', 'Various experiments demonstrate that CoDAIL can better regenerate complex interactions close to the demonstrators and outperforms state-of-the-art multi-agent imitation learning methods.', 'Our code is available at \\url{https://github.com/apexrl/CoDAIL}.']
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B1gZV1HYvS
['Modeling complex multi-agent interactions under multi-agent imitation learning framework with explicit modeling of correlated policies by approximating opponents’ policies. ']
In multi-agent systems, complex interacting behaviors arise due to the high correlations among agents., However, previous work on modeling multi-agent interactions from demonstrations is primarily constrained by assuming the independence among policies and their reward structures. , In this paper, we cast the multi-agent interactions modeling problem into a multi-agent imitation learning framework with explicit modeling of correlated policies by approximating opponents’ policies, which can recover agents' policies that can regenerate similar interactions., Consequently, we develop a Decentralized Adversarial Imitation Learning algorithm with Correlated policies (CoDAIL), which allows for decentralized training and execution., Various experiments demonstrate that CoDAIL can better regenerate complex interactions close to the demonstrators and outperforms state-of-the-art multi-agent imitation learning methods., Our code is available at \url{https://github.com/apexrl/CoDAIL}.
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['Plagiarism and text reuse become more available with the Internet development.', 'Therefore it is important to check scientific papers for the fact of cheating, especially in Academia.', 'Existing systems of plagiarism detection show the good performance and have a huge source databases.', 'Thus now it is not enough just to copy the text as is from the source document to get the original work.', 'Therefore, another type of plagiarism become popular -- cross-lingual plagiarism.', 'We present a CrossLang system for such kind of plagiarism detection for English-Russian language pair.']
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BkxiG6qqIr
['A system for cross-lingual (English-Russian) plagiarism detection']
Plagiarism and text reuse become more available with the Internet development., Therefore it is important to check scientific papers for the fact of cheating, especially in Academia., Existing systems of plagiarism detection show the good performance and have a huge source databases., Thus now it is not enough just to copy the text as is from the source document to get the original work., Therefore, another type of plagiarism become popular -- cross-lingual plagiarism., We present a CrossLang system for such kind of plagiarism detection for English-Russian language pair.
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['Data parallelism has become a dominant method to scale Deep Neural Network (DNN) training across multiple nodes. ', 'Since the synchronization of the local models or gradients can be a bottleneck for large-scale distributed training, compressing communication traffic has gained widespread attention recently. ', 'Among several recent proposed compression algorithms, \nResidual Gradient Compression (RGC) is one of the most successful approaches---it can significantly compress the transmitting message size (0.1% of the gradient size) of each node and still preserve accuracy.', 'However, the literature on compressing deep networks focuses almost exclusively on achieving good compression rate, while the efficiency of RGC in real implementation has been less investigated.', 'In this paper, we develop an RGC method that achieves significant training time improvement in real-world multi-GPU systems.', 'Our proposed RGC system design called RedSync, introduces a set of optimizations to reduce communication bandwidth while introducing limited overhead.', 'We examine the performance of RedSync on two different multiple GPU platforms, including a supercomputer and a multi-card server.', 'Our test cases include image classification on Cifar10 and ImageNet, and language modeling tasks on Penn Treebank and Wiki2 datasets.', 'For DNNs featured with high communication to computation ratio, which has long been considered with poor scalability, RedSync shows significant performance improvement.']
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rkxJus0cFX
['We proposed an implementation to accelerate DNN data parallel training by reducing communication bandwidth requirement.']
Data parallelism has become a dominant method to scale Deep Neural Network (DNN) training across multiple nodes. , Since the synchronization of the local models or gradients can be a bottleneck for large-scale distributed training, compressing communication traffic has gained widespread attention recently. , Among several recent proposed compression algorithms, Residual Gradient Compression (RGC) is one of the most successful approaches---it can significantly compress the transmitting message size (0.1% of the gradient size) of each node and still preserve accuracy., However, the literature on compressing deep networks focuses almost exclusively on achieving good compression rate, while the efficiency of RGC in real implementation has been less investigated., In this paper, we develop an RGC method that achieves significant training time improvement in real-world multi-GPU systems., Our proposed RGC system design called RedSync, introduces a set of optimizations to reduce communication bandwidth while introducing limited overhead., We examine the performance of RedSync on two different multiple GPU platforms, including a supercomputer and a multi-card server., Our test cases include image classification on Cifar10 and ImageNet, and language modeling tasks on Penn Treebank and Wiki2 datasets., For DNNs featured with high communication to computation ratio, which has long been considered with poor scalability, RedSync shows significant performance improvement.
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["Backpropagation is driving today's artificial neural networks.", 'However, despite extensive research, it remains unclear if the brain implements this algorithm.', 'Among neuroscientists, reinforcement learning (RL) algorithms are often seen as a realistic alternative.', 'However, the convergence rate of such learning scales poorly with the number of involved neurons.', 'Here we propose a hybrid learning approach, in which each neuron uses an RL-type strategy to learn how to approximate the gradients that backpropagation would provide.', 'We show that our approach learns to approximate the gradient, and can match the performance of gradient-based learning on fully connected and convolutional networks.', 'Learning feedback weights provides a biologically plausible mechanism of achieving good performance, without the need for precise, pre-specified learning rules.']
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ByxfNXF8Ir
['Perturbations can be used to learn feedback weights on large fully connected and convolutional networks.']
Backpropagation is driving today's artificial neural networks., However, despite extensive research, it remains unclear if the brain implements this algorithm., Among neuroscientists, reinforcement learning (RL) algorithms are often seen as a realistic alternative., However, the convergence rate of such learning scales poorly with the number of involved neurons., Here we propose a hybrid learning approach, in which each neuron uses an RL-type strategy to learn how to approximate the gradients that backpropagation would provide., We show that our approach learns to approximate the gradient, and can match the performance of gradient-based learning on fully connected and convolutional networks., Learning feedback weights provides a biologically plausible mechanism of achieving good performance, without the need for precise, pre-specified learning rules.
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['Most deep neural networks (DNNs) require complex models to achieve high performance.', 'Parameter quantization is widely used for reducing the implementation complexities.', 'Previous studies on quantization were mostly based on extensive simulation using training data.', 'We choose a different approach and attempt to measure the per-parameter capacity of DNN models and interpret the results to obtain insights on optimum quantization of parameters.', 'This research uses artificially generated data and generic forms of fully connected DNNs, convolutional neural networks, and recurrent neural networks.', 'We conduct memorization and classification tests to study the effects of the number and precision of the parameters on the performance.', 'The model and the per-parameter capacities are assessed by measuring the mutual information between the input and the classified output.', 'We also extend the memorization capacity measurement results to image classification and language modeling tasks.', 'To get insight for parameter quantization when performing real tasks, the training and test performances are compared.']
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HylIcj0qFQ
['We suggest the sufficient number of bits for representing weights of DNNs and the optimum bits are conservative when solving real problems.']
Most deep neural networks (DNNs) require complex models to achieve high performance., Parameter quantization is widely used for reducing the implementation complexities., Previous studies on quantization were mostly based on extensive simulation using training data., We choose a different approach and attempt to measure the per-parameter capacity of DNN models and interpret the results to obtain insights on optimum quantization of parameters., This research uses artificially generated data and generic forms of fully connected DNNs, convolutional neural networks, and recurrent neural networks., We conduct memorization and classification tests to study the effects of the number and precision of the parameters on the performance., The model and the per-parameter capacities are assessed by measuring the mutual information between the input and the classified output., We also extend the memorization capacity measurement results to image classification and language modeling tasks., To get insight for parameter quantization when performing real tasks, the training and test performances are compared.
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['Inspired by the combination of feedforward and iterative computations in the visual cortex, and taking advantage of the ability of denoising autoencoders to estimate the score of a joint distribution, we propose a novel approach to iterative inference for capturing and exploiting the complex joint distribution of output variables conditioned on some input variables.', 'This approach is applied to image pixel-wise segmentation, with the estimated conditional score used to perform gradient ascent towards a mode of the estimated conditional distribution.', 'This extends previous work on score estimation by denoising autoencoders to the case of a conditional distribution, with a novel use of a corrupted feedforward predictor replacing Gaussian corruption.', 'An advantage of this approach over more classical ways to perform iterative inference for structured outputs, like conditional random fields (CRFs), is that it is not any more necessary to define an explicit energy function linking the output variables.', 'To keep computations tractable, such energy function parametrizations are typically fairly constrained, involving only a few neighbors of each of the output variables in each clique.', 'We experimentally find that the proposed iterative inference from conditional score estimation by conditional denoising autoencoders performs better than comparable models based on CRFs or those not using any explicit modeling of the conditional joint distribution of outputs.']
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HklpCzC6-
['Refining segmentation proposals by performing iterative inference with conditional denoising autoencoders.']
Inspired by the combination of feedforward and iterative computations in the visual cortex, and taking advantage of the ability of denoising autoencoders to estimate the score of a joint distribution, we propose a novel approach to iterative inference for capturing and exploiting the complex joint distribution of output variables conditioned on some input variables., This approach is applied to image pixel-wise segmentation, with the estimated conditional score used to perform gradient ascent towards a mode of the estimated conditional distribution., This extends previous work on score estimation by denoising autoencoders to the case of a conditional distribution, with a novel use of a corrupted feedforward predictor replacing Gaussian corruption., An advantage of this approach over more classical ways to perform iterative inference for structured outputs, like conditional random fields (CRFs), is that it is not any more necessary to define an explicit energy function linking the output variables., To keep computations tractable, such energy function parametrizations are typically fairly constrained, involving only a few neighbors of each of the output variables in each clique., We experimentally find that the proposed iterative inference from conditional score estimation by conditional denoising autoencoders performs better than comparable models based on CRFs or those not using any explicit modeling of the conditional joint distribution of outputs.
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['Inspired by the success of self attention mechanism and Transformer architecture\n', 'in sequence transduction and image generation applications, we propose novel self\n', 'attention-based architectures to improve the performance of adversarial latent code-\n', 'based schemes in text generation.', 'Adversarial latent code-based text generation\n', 'has recently gained a lot of attention due to their promising results.', 'In this paper,\n', 'we take a step to fortify the architectures used in these setups, specifically AAE\n', 'and ARAE.', 'We benchmark two latent code-based methods (AAE and ARAE)\n', 'designed based on adversarial setups.', 'In our experiments, the Google sentence\n', 'compression dataset is utilized to compare our method with these methods using\n', 'various objective and subjective measures.', 'The experiments demonstrate the\n', 'proposed (self) attention-based models outperform the state-of-the-art in adversarial\n', 'code-based text generation.']
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[0.13793103396892548, 0.20689654350280762, 0.1428571343421936, 0.260869562625885, 0.260869562625885, 0.13333332538604736, 0.0, 0.0624999962747097, 0.2222222238779068, 0.260869562625885, 0.0, 0.0, 0.08695651590824127, 0.0, 0.07407406717538834, 0.2857142686843872]
B1liWh09F7
['We propose a self-attention based GAN architecture for unconditional text generation and improve on previous adversarial code-based results.']
Inspired by the success of self attention mechanism and Transformer architecture , in sequence transduction and image generation applications, we propose novel self , attention-based architectures to improve the performance of adversarial latent code- , based schemes in text generation., Adversarial latent code-based text generation , has recently gained a lot of attention due to their promising results., In this paper, , we take a step to fortify the architectures used in these setups, specifically AAE , and ARAE., We benchmark two latent code-based methods (AAE and ARAE) , designed based on adversarial setups., In our experiments, the Google sentence , compression dataset is utilized to compare our method with these methods using , various objective and subjective measures., The experiments demonstrate the , proposed (self) attention-based models outperform the state-of-the-art in adversarial , code-based text generation.
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['Watermarks have been used for various purposes.', 'Recently, researchers started to look into using them for deep neural networks.', 'Some works try to hide attack triggers on their adversarial samples when attacking neural networks and others want to watermark neural networks to prove their ownership against plagiarism.', 'Implanting a backdoor watermark module into a neural network is getting more attention from the community.', 'In this paper, we present a general purpose encoder-decoder joint training method, inspired by generative adversarial networks (GANs).', 'Unlike GANs, however, our encoder and decoder neural networks cooperate to find the best watermarking scheme given data samples.', 'In other words, we do not design any new watermarking strategy but our proposed two neural networks will find the best suited method on their own.', 'After being trained, the decoder can be implanted into other neural networks to attack or protect them (see Appendix for their use cases and real implementations).', 'To this end, the decoder should be very tiny in order not to incur any overhead when attached to other neural networks but at the same time provide very high decoding success rates, which is very challenging.', 'Our joint training method successfully solves the problem and in our experiments maintain almost 100\\% encoding-decoding success rates for multiple datasets with very little modifications on data samples to hide watermarks.', 'We also present several real-world use cases in Appendix.']
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ryfDoiR5Ym
['We propose a novel watermark encoder-decoder neural networks. They perform a cooperative game to define their own watermarking scheme. People do not need to design watermarking methods any more.']
Watermarks have been used for various purposes., Recently, researchers started to look into using them for deep neural networks., Some works try to hide attack triggers on their adversarial samples when attacking neural networks and others want to watermark neural networks to prove their ownership against plagiarism., Implanting a backdoor watermark module into a neural network is getting more attention from the community., In this paper, we present a general purpose encoder-decoder joint training method, inspired by generative adversarial networks (GANs)., Unlike GANs, however, our encoder and decoder neural networks cooperate to find the best watermarking scheme given data samples., In other words, we do not design any new watermarking strategy but our proposed two neural networks will find the best suited method on their own., After being trained, the decoder can be implanted into other neural networks to attack or protect them (see Appendix for their use cases and real implementations)., To this end, the decoder should be very tiny in order not to incur any overhead when attached to other neural networks but at the same time provide very high decoding success rates, which is very challenging., Our joint training method successfully solves the problem and in our experiments maintain almost 100\% encoding-decoding success rates for multiple datasets with very little modifications on data samples to hide watermarks., We also present several real-world use cases in Appendix.
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['We derive an unbiased estimator for expectations over discrete random variables based on sampling without replacement, which reduces variance as it avoids duplicate samples.', 'We show that our estimator can be derived as the Rao-Blackwellization of three different estimators.', 'Combining our estimator with REINFORCE, we obtain a policy gradient estimator and we reduce its variance using a built-in control variate which is obtained without additional model evaluations.', 'The resulting estimator is closely related to other gradient estimators.', 'Experiments with a toy problem, a categorical Variational Auto-Encoder and a structured prediction problem show that our estimator is the only estimator that is consistently among the best estimators in both high and low entropy settings.']
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[0.6666666865348816, 0.12121211737394333, 0.1860465109348297, 0.1428571343421936, 0.08510638028383255]
rklEj2EFvB
['We derive a low-variance, unbiased gradient estimator for expectations over discrete random variables based on sampling without replacement']
We derive an unbiased estimator for expectations over discrete random variables based on sampling without replacement, which reduces variance as it avoids duplicate samples., We show that our estimator can be derived as the Rao-Blackwellization of three different estimators., Combining our estimator with REINFORCE, we obtain a policy gradient estimator and we reduce its variance using a built-in control variate which is obtained without additional model evaluations., The resulting estimator is closely related to other gradient estimators., Experiments with a toy problem, a categorical Variational Auto-Encoder and a structured prediction problem show that our estimator is the only estimator that is consistently among the best estimators in both high and low entropy settings.
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['We introduce a parameter sharing scheme, in which different layers of a convolutional neural network (CNN) are defined by a learned linear combination of parameter tensors from a global bank of templates. ', 'Restricting the number of templates yields a flexible hybridization of traditional CNNs and recurrent networks. ', 'Compared to traditional CNNs, we demonstrate substantial parameter savings on standard image classification tasks, while maintaining accuracy.\n', 'Our simple parameter sharing scheme, though defined via soft weights, in practice often yields trained networks with near strict recurrent structure; with negligible side effects, they convert into networks with actual loops.', 'Training these networks thus implicitly involves discovery of suitable recurrent architectures.', 'Though considering only the aspect of recurrent links, our trained networks achieve accuracy competitive with those built using state-of-the-art neural architecture search (NAS) procedures.\n', 'Our hybridization of recurrent and convolutional networks may also represent a beneficial architectural bias. ', 'Specifically, on synthetic tasks which are algorithmic in nature, our hybrid networks both train faster and extrapolate better to test examples outside the span of the training set.']
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[0.10256409645080566, 0.14814814925193787, 0.06666666269302368, 0.04878048226237297, 0.08695651590824127, 0.05405404791235924, 0.14814814925193787, 0.05128204822540283]
rJgYxn09Fm
['We propose a method that enables CNN folding to create recurrent connections']
We introduce a parameter sharing scheme, in which different layers of a convolutional neural network (CNN) are defined by a learned linear combination of parameter tensors from a global bank of templates. , Restricting the number of templates yields a flexible hybridization of traditional CNNs and recurrent networks. , Compared to traditional CNNs, we demonstrate substantial parameter savings on standard image classification tasks, while maintaining accuracy. , Our simple parameter sharing scheme, though defined via soft weights, in practice often yields trained networks with near strict recurrent structure; with negligible side effects, they convert into networks with actual loops., Training these networks thus implicitly involves discovery of suitable recurrent architectures., Though considering only the aspect of recurrent links, our trained networks achieve accuracy competitive with those built using state-of-the-art neural architecture search (NAS) procedures. , Our hybridization of recurrent and convolutional networks may also represent a beneficial architectural bias. , Specifically, on synthetic tasks which are algorithmic in nature, our hybrid networks both train faster and extrapolate better to test examples outside the span of the training set.
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['Gradient clipping is a widely-used technique in the training of deep networks, and is generally motivated from an optimisation lens: informally, it controls the dynamics of iterates, thus enhancing the rate of convergence to a local minimum.', 'This intuition has been made precise in a line of recent works, which show that suitable clipping can yield significantly faster convergence than vanilla gradient descent.', 'In this paper, we propose a new lens for studying gradient clipping, namely, robustness: informally, one expects clipping to provide robustness to noise, since one does not overly trust any single sample.', 'Surprisingly, we prove that for the common problem of label noise in classification, standard gradient clipping does not in general provide robustness.', 'On the other hand, we show that a simple variant of gradient clipping is provably robust, and corresponds to suitably modifying the underlying loss function.', 'This yields a simple, noise-robust alternative to the standard cross-entropy loss which performs well empirically.']
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rklB76EKPr
["Gradient clipping doesn't endow robustness to label noise, but a simple loss-based variant does."]
Gradient clipping is a widely-used technique in the training of deep networks, and is generally motivated from an optimisation lens: informally, it controls the dynamics of iterates, thus enhancing the rate of convergence to a local minimum., This intuition has been made precise in a line of recent works, which show that suitable clipping can yield significantly faster convergence than vanilla gradient descent., In this paper, we propose a new lens for studying gradient clipping, namely, robustness: informally, one expects clipping to provide robustness to noise, since one does not overly trust any single sample., Surprisingly, we prove that for the common problem of label noise in classification, standard gradient clipping does not in general provide robustness., On the other hand, we show that a simple variant of gradient clipping is provably robust, and corresponds to suitably modifying the underlying loss function., This yields a simple, noise-robust alternative to the standard cross-entropy loss which performs well empirically.
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[' Among deep generative models, flow-based models, simply referred as \\emph{flow}s in this paper, differ from other models in that they provide tractable likelihood.', 'Besides being an evaluation metric of synthesized data, flows are supposed to be robust against out-of-distribution~(OoD) inputs since they do not discard any information of the inputs.', 'However, it has been observed that flows trained on FashionMNIST assign higher likelihoods to OoD samples from MNIST.', "This counter-intuitive observation raises the concern about the robustness of flows' likelihood.", "In this paper, we explore the correlation between flows' likelihood and image semantics.", 'We choose two typical flows as the target models: Glow, based on coupling transformations, and pixelCNN, based on autoregressive transformations.', "Our experiments reveal surprisingly weak correlation between flows' likelihoods and image semantics: the predictive likelihoods of flows can be heavily affected by trivial transformations that keep the image semantics unchanged, which we call semantic-invariant transformations~(SITs).", 'We explore three SITs~(all small pixel-level modifications): image pixel translation, random noise perturbation, latent factors zeroing~(limited to flows using multi-scale architecture, e.g. Glow).', 'These findings, though counter-intuitive, resonate with the fact that the predictive likelihood of a flow is the joint probability of all the image pixels.', "So flows' likelihoods, modeling on pixel-level intensities, is not able to indicate the existence likelihood of the high-level image semantics.", 'We call for attention that it may be \\emph{abuse} if we use the predictive likelihoods of flows for OoD samples detection.']
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rkgIllBtwB
["show experimental evidences about the weak correlation between flows' likelihoods and image semantics."]
Among deep generative models, flow-based models, simply referred as \emph{flow}s in this paper, differ from other models in that they provide tractable likelihood., Besides being an evaluation metric of synthesized data, flows are supposed to be robust against out-of-distribution~(OoD) inputs since they do not discard any information of the inputs., However, it has been observed that flows trained on FashionMNIST assign higher likelihoods to OoD samples from MNIST., This counter-intuitive observation raises the concern about the robustness of flows' likelihood., In this paper, we explore the correlation between flows' likelihood and image semantics., We choose two typical flows as the target models: Glow, based on coupling transformations, and pixelCNN, based on autoregressive transformations., Our experiments reveal surprisingly weak correlation between flows' likelihoods and image semantics: the predictive likelihoods of flows can be heavily affected by trivial transformations that keep the image semantics unchanged, which we call semantic-invariant transformations~(SITs)., We explore three SITs~(all small pixel-level modifications): image pixel translation, random noise perturbation, latent factors zeroing~(limited to flows using multi-scale architecture, e.g. Glow)., These findings, though counter-intuitive, resonate with the fact that the predictive likelihood of a flow is the joint probability of all the image pixels., So flows' likelihoods, modeling on pixel-level intensities, is not able to indicate the existence likelihood of the high-level image semantics., We call for attention that it may be \emph{abuse} if we use the predictive likelihoods of flows for OoD samples detection.
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['This paper investigates strategies that defend against adversarial-example attacks on image-classification systems by transforming the inputs before feeding them to the system.', 'Specifically, we study applying image transformations such as bit-depth reduction, JPEG compression, total variance minimization, and image quilting before feeding the image to a convolutional network classifier.', 'Our experiments on ImageNet show that total variance minimization and image quilting are very effective defenses in practice, in particular, when the network is trained on transformed images.', 'The strength of those defenses lies in their non-differentiable nature and their inherent randomness, which makes it difficult for an adversary to circumvent the defenses.', 'Our best defense eliminates 60% of strong gray-box and 90% of strong black-box attacks by a variety of major attack methods.']
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SyJ7ClWCb
['We apply a model-agnostic defense strategy against adversarial examples and achieve 60% white-box accuracy and 90% black-box accuracy against major attack algorithms.']
This paper investigates strategies that defend against adversarial-example attacks on image-classification systems by transforming the inputs before feeding them to the system., Specifically, we study applying image transformations such as bit-depth reduction, JPEG compression, total variance minimization, and image quilting before feeding the image to a convolutional network classifier., Our experiments on ImageNet show that total variance minimization and image quilting are very effective defenses in practice, in particular, when the network is trained on transformed images., The strength of those defenses lies in their non-differentiable nature and their inherent randomness, which makes it difficult for an adversary to circumvent the defenses., Our best defense eliminates 60% of strong gray-box and 90% of strong black-box attacks by a variety of major attack methods.
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['\tIn this paper, we propose the Asynchronous Accelerated Nonuniform Randomized Block Coordinate Descent algorithm (A2BCD).', 'We prove A2BCD converges linearly to a solution of the convex minimization problem at the same rate as NU_ACDM, so long as the maximum delay is not too large.', 'This is the first asynchronous Nesterov-accelerated algorithm that attains any provable speedup.', 'Moreover, we then prove that these algorithms both have optimal complexity.', 'Asynchronous algorithms complete much faster iterations, and A2BCD has optimal complexity.', 'Hence we observe in experiments that A2BCD is the top-performing coordinate descent algorithm, converging up to 4-5x faster than NU_ACDM on some data sets in terms of wall-clock time.', 'To motivate our theory and proof techniques, we also derive and analyze a continuous-time analog of our algorithm and prove it converges at the same rate.']
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rylIAsCqYm
['We prove the first-ever convergence proof of an asynchronous accelerated algorithm that attains a speedup.']
In this paper, we propose the Asynchronous Accelerated Nonuniform Randomized Block Coordinate Descent algorithm (A2BCD)., We prove A2BCD converges linearly to a solution of the convex minimization problem at the same rate as NU_ACDM, so long as the maximum delay is not too large., This is the first asynchronous Nesterov-accelerated algorithm that attains any provable speedup., Moreover, we then prove that these algorithms both have optimal complexity., Asynchronous algorithms complete much faster iterations, and A2BCD has optimal complexity., Hence we observe in experiments that A2BCD is the top-performing coordinate descent algorithm, converging up to 4-5x faster than NU_ACDM on some data sets in terms of wall-clock time., To motivate our theory and proof techniques, we also derive and analyze a continuous-time analog of our algorithm and prove it converges at the same rate.
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['A framework for efficient Bayesian inference in probabilistic programs is introduced by embedding a sampler inside a variational posterior approximation.', 'Its strength lies in both ease of implementation and automatically tuning sampler parameters to speed up mixing time.', 'Several strategies to approximate the evidence lower bound (ELBO) computation are introduced, including a rewriting of the ELBO objective.', 'Experimental evidence is shown by performing experiments on an unconditional VAE on density estimation tasks; solving an influence diagram in a high-dimensional space with a conditional variational autoencoder (cVAE) as a deep Bayes classifier; and state-space models for time-series data.']
[1, 0, 0, 0]
[0.29629629850387573, 0.0, 0.07692307233810425, 0.09090908616781235]
Hkglty2EKH
['We embed SG-MCMC samplers inside a variational approximation']
A framework for efficient Bayesian inference in probabilistic programs is introduced by embedding a sampler inside a variational posterior approximation., Its strength lies in both ease of implementation and automatically tuning sampler parameters to speed up mixing time., Several strategies to approximate the evidence lower bound (ELBO) computation are introduced, including a rewriting of the ELBO objective., Experimental evidence is shown by performing experiments on an unconditional VAE on density estimation tasks; solving an influence diagram in a high-dimensional space with a conditional variational autoencoder (cVAE) as a deep Bayes classifier; and state-space models for time-series data.
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['The point estimates of ReLU classification networks, arguably the most widely used neural network architecture, have recently been shown to have arbitrarily high confidence far away from the training data.', 'This architecture is thus not robust, e.g., against out-of-distribution data.', 'Approximate Bayesian posteriors on the weight space have been empirically demonstrated to improve predictive uncertainty in deep learning.', 'The theoretical analysis of such Bayesian approximations is limited, including for ReLU classification networks.', 'We present an analysis of approximate Gaussian posterior distributions on the weights of ReLU networks.', 'We show that even a simplistic (thus cheap), non-Bayesian Gaussian distribution fixes the asymptotic overconfidence issue.', 'Furthermore, when a Bayesian method, even if a simple one, is employed to obtain the Gaussian, the confidence becomes better calibrated.', 'This theoretical result motivates a range of Laplace approximations along a fidelity-cost trade-off.', 'We validate these findings empirically via experiments using common deep ReLU networks.']
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H1gJ2RVFPH
['We argue theoretically that by simply assuming the weights of a ReLU network to be Gaussian distributed (without even a Bayesian formalism) could fix this issue; for a more calibrated uncertainty, a simple Bayesian method could already be sufficient.']
The point estimates of ReLU classification networks, arguably the most widely used neural network architecture, have recently been shown to have arbitrarily high confidence far away from the training data., This architecture is thus not robust, e.g., against out-of-distribution data., Approximate Bayesian posteriors on the weight space have been empirically demonstrated to improve predictive uncertainty in deep learning., The theoretical analysis of such Bayesian approximations is limited, including for ReLU classification networks., We present an analysis of approximate Gaussian posterior distributions on the weights of ReLU networks., We show that even a simplistic (thus cheap), non-Bayesian Gaussian distribution fixes the asymptotic overconfidence issue., Furthermore, when a Bayesian method, even if a simple one, is employed to obtain the Gaussian, the confidence becomes better calibrated., This theoretical result motivates a range of Laplace approximations along a fidelity-cost trade-off., We validate these findings empirically via experiments using common deep ReLU networks.
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['Word alignments are useful for tasks like statistical and neural machine translation (NMT) and annotation projection.', 'Statistical word aligners perform well, as do methods that extract alignments jointly with translations in NMT.', 'However, most approaches require parallel training data and quality decreases as less training data is available.', 'We propose word alignment methods that require little or no parallel data.', 'The key idea is to leverage multilingual word embeddings – both static and contextualized – for word alignment.', 'Our multilingual embeddings are created from monolingual data only without relying on any parallel data or dictionaries.', 'We find that traditional statistical aligners are outperformed by contextualized embeddings – even in scenarios with abundant parallel data.', 'For example, for a set of 100k parallel sentences, contextualized embeddings achieve a word alignment F1 that is more than 5% higher (absolute) than eflomal.']
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[0.14814814925193787, 0.1428571343421936, 0.1538461446762085, 0.3333333134651184, 0.1428571343421936, 0.2857142686843872, 0.19354838132858276, 0.17142856121063232]
SFIxZr3RRpr
['We use representations trained without any parallel data for creating word alignments.']
Word alignments are useful for tasks like statistical and neural machine translation (NMT) and annotation projection., Statistical word aligners perform well, as do methods that extract alignments jointly with translations in NMT., However, most approaches require parallel training data and quality decreases as less training data is available., We propose word alignment methods that require little or no parallel data., The key idea is to leverage multilingual word embeddings – both static and contextualized – for word alignment., Our multilingual embeddings are created from monolingual data only without relying on any parallel data or dictionaries., We find that traditional statistical aligners are outperformed by contextualized embeddings – even in scenarios with abundant parallel data., For example, for a set of 100k parallel sentences, contextualized embeddings achieve a word alignment F1 that is more than 5% higher (absolute) than eflomal.
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['Recent studies have shown the vulnerability of reinforcement learning (RL) models in noisy settings.', 'The sources of noises differ across scenarios.', 'For instance, in practice, the observed reward channel is often subject to noise (e.g., when observed rewards are collected through sensors), and thus observed rewards may not be credible as a result.', 'Also, in applications such as robotics, a deep reinforcement learning (DRL) algorithm can be manipulated to produce arbitrary errors.', 'In this paper, we consider noisy RL problems where observed rewards by RL agents are generated with a reward confusion matrix.', 'We call such observed rewards as perturbed rewards.', 'We develop an unbiased reward estimator aided robust RL framework that enables RL agents to learn in noisy environments while observing only perturbed rewards.', 'Our framework draws upon approaches for supervised learning with noisy data.', 'The core ideas of our solution include estimating a reward confusion matrix and defining a set of unbiased surrogate rewards.', 'We prove the convergence and sample complexity of our approach.', 'Extensive experiments on different DRL platforms show that policies based on our estimated surrogate reward can achieve higher expected rewards, and converge faster than existing baselines.', 'For instance, the state-of-the-art PPO algorithm is able to obtain 67.5% and 46.7% improvements in average on five Atari games, when the error rates are 10% and 30% respectively.']
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BkMWx309FX
['A new approach for learning with noisy rewards in reinforcement learning']
Recent studies have shown the vulnerability of reinforcement learning (RL) models in noisy settings., The sources of noises differ across scenarios., For instance, in practice, the observed reward channel is often subject to noise (e.g., when observed rewards are collected through sensors), and thus observed rewards may not be credible as a result., Also, in applications such as robotics, a deep reinforcement learning (DRL) algorithm can be manipulated to produce arbitrary errors., In this paper, we consider noisy RL problems where observed rewards by RL agents are generated with a reward confusion matrix., We call such observed rewards as perturbed rewards., We develop an unbiased reward estimator aided robust RL framework that enables RL agents to learn in noisy environments while observing only perturbed rewards., Our framework draws upon approaches for supervised learning with noisy data., The core ideas of our solution include estimating a reward confusion matrix and defining a set of unbiased surrogate rewards., We prove the convergence and sample complexity of our approach., Extensive experiments on different DRL platforms show that policies based on our estimated surrogate reward can achieve higher expected rewards, and converge faster than existing baselines., For instance, the state-of-the-art PPO algorithm is able to obtain 67.5% and 46.7% improvements in average on five Atari games, when the error rates are 10% and 30% respectively.
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['Training recurrent neural networks (RNNs) on long sequences using backpropagation through time (BPTT) remains a fundamental challenge. \n', 'It has been shown that adding a local unsupervised loss term into the optimization objective makes the training of RNNs on long sequences more effective. \n', 'While the importance of an unsupervised task can in principle be controlled by a coefficient in the objective function, the gradients with respect to the unsupervised loss term still influence all the hidden state dimensions, which might cause important information about the supervised task to be degraded or erased. \n', 'Compared to existing semi-supervised sequence learning methods, this paper focuses upon a traditionally overlooked mechanism -- an architecture with explicitly designed private and shared hidden units designed to mitigate the detrimental influence of the auxiliary unsupervised loss over the main supervised task.\n', 'We achieve this by dividing RNN hidden space into a private space for the supervised task and a shared space for both the supervised and unsupervised tasks.', 'We present extensive experiments with the proposed framework on several long sequence modeling benchmark datasets.', 'Results indicate that the proposed framework can yield performance gains in RNN models where long term dependencies are notoriously challenging to deal with.']
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r1lcM3AcKm
['This paper focuses upon a traditionally overlooked mechanism -- an architecture with explicitly designed private and shared hidden units designed to mitigate the detrimental influence of the auxiliary unsupervised loss over the main supervised task.']
Training recurrent neural networks (RNNs) on long sequences using backpropagation through time (BPTT) remains a fundamental challenge. , It has been shown that adding a local unsupervised loss term into the optimization objective makes the training of RNNs on long sequences more effective. , While the importance of an unsupervised task can in principle be controlled by a coefficient in the objective function, the gradients with respect to the unsupervised loss term still influence all the hidden state dimensions, which might cause important information about the supervised task to be degraded or erased. , Compared to existing semi-supervised sequence learning methods, this paper focuses upon a traditionally overlooked mechanism -- an architecture with explicitly designed private and shared hidden units designed to mitigate the detrimental influence of the auxiliary unsupervised loss over the main supervised task. , We achieve this by dividing RNN hidden space into a private space for the supervised task and a shared space for both the supervised and unsupervised tasks., We present extensive experiments with the proposed framework on several long sequence modeling benchmark datasets., Results indicate that the proposed framework can yield performance gains in RNN models where long term dependencies are notoriously challenging to deal with.
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['We investigate multi-task learning approaches which use a shared feature representation for all tasks.', 'To better understand the transfer of task information, we study an architecture with a shared module for all tasks and a separate output module for each task.', 'We study the theory of this setting on linear and ReLU-activated models.', "Our key observation is that whether or not tasks' data are well-aligned can significantly affect the performance of multi-task learning.", 'We show that misalignment between task data can cause negative transfer (or hurt performance) and provide sufficient conditions for positive transfer.', "Inspired by the theoretical insights, we show that aligning tasks' embedding layers leads to performance gains for multi-task training and transfer learning on the GLUE benchmark and sentiment analysis tasks; for example, we obtained a 2.35% GLUE score average improvement on 5 GLUE tasks over BERT LARGE using our alignment method.", 'We also design an SVD-based task re-weighting scheme and show that it improves the robustness of multi-task training on a multi-label image dataset.']
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[0.0714285671710968, 0.21621620655059814, 0.1538461446762085, 0.05882352590560913, 0.11764705181121826, 0.06779660284519196, 0.10810810327529907]
SylzhkBtDB
['A Theoretical Study of Multi-Task Learning with Practical Implications for Improving Multi-Task Training and Transfer Learning']
We investigate multi-task learning approaches which use a shared feature representation for all tasks., To better understand the transfer of task information, we study an architecture with a shared module for all tasks and a separate output module for each task., We study the theory of this setting on linear and ReLU-activated models., Our key observation is that whether or not tasks' data are well-aligned can significantly affect the performance of multi-task learning., We show that misalignment between task data can cause negative transfer (or hurt performance) and provide sufficient conditions for positive transfer., Inspired by the theoretical insights, we show that aligning tasks' embedding layers leads to performance gains for multi-task training and transfer learning on the GLUE benchmark and sentiment analysis tasks; for example, we obtained a 2.35% GLUE score average improvement on 5 GLUE tasks over BERT LARGE using our alignment method., We also design an SVD-based task re-weighting scheme and show that it improves the robustness of multi-task training on a multi-label image dataset.
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['We review three limitations of BLEU and ROUGE – the most popular metrics\n', 'used to assess reference summaries against hypothesis summaries, come up with\n', 'criteria for what a good metric should behave like and propose concrete ways to\n', 'assess the performance of a metric in detail and show the potential of Transformers-based Language Models to assess reference summaries against hypothesis summaries.']
[1, 0, 0, 0]
[0.3125, 0.0, 0.12121211737394333, 0.2631579041481018]
S1xkQac9LB
['New method for assessing the quaility of similarity evaluators and showing potential of Transformer-based language models in replacing BLEU and ROUGE.']
We review three limitations of BLEU and ROUGE – the most popular metrics , used to assess reference summaries against hypothesis summaries, come up with , criteria for what a good metric should behave like and propose concrete ways to , assess the performance of a metric in detail and show the potential of Transformers-based Language Models to assess reference summaries against hypothesis summaries.
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['In this paper, we explore meta-learning for few-shot text classification.', 'Meta-learning has shown strong performance in computer vision, where low-level patterns are transferable across learning tasks.', 'However, directly applying this approach to text is challenging–lexical features highly informative for one task maybe insignificant for another.', 'Thus, rather than learning solely from words, our model also leverages their distributional signatures, which encode pertinent word occurrence patterns.', 'Our model is trained within a meta-learning framework to map these signatures into attention scores, which are then used to weight the lexical representations of words.', 'We demonstrate that our model consistently outperforms prototypical networks learned on lexical knowledge (Snell et al., 2017) in both few-shot text classification and relation classification by a significant margin across six benchmark datasets (19.96% on average in 1-shot classification).']
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H1emfT4twB
['Meta-learning methods used for vision, directly applied to NLP, perform worse than nearest neighbors on new classes; we can do better with distributional signatures.']
In this paper, we explore meta-learning for few-shot text classification., Meta-learning has shown strong performance in computer vision, where low-level patterns are transferable across learning tasks., However, directly applying this approach to text is challenging–lexical features highly informative for one task maybe insignificant for another., Thus, rather than learning solely from words, our model also leverages their distributional signatures, which encode pertinent word occurrence patterns., Our model is trained within a meta-learning framework to map these signatures into attention scores, which are then used to weight the lexical representations of words., We demonstrate that our model consistently outperforms prototypical networks learned on lexical knowledge (Snell et al., 2017) in both few-shot text classification and relation classification by a significant margin across six benchmark datasets (19.96% on average in 1-shot classification).
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['The description of neural computations in the field of neuroscience relies on two competing views:', '(i) a classical single-cell view that relates the activity of individual neurons to sensory or behavioural variables, and focuses on how different cell classes map onto computations;', '(ii) a more recent population view that instead characterises computations in terms of collective neural trajectories, and focuses on the dimensionality of these trajectories as animals perform tasks.', 'How the two key concepts of cell classes and low-dimensional trajectories interact to shape neural computations is however currently not understood.', 'Here we address this question by combining machine-learning tools for training RNNs with reverse-engineering and theoretical analyses of network dynamics.', 'We introduce a novel class of theoretically tractable recurrent networks: low-rank, mixture of Gaussian RNNs.', 'In these networks, the rank of the connectivity controls the dimensionality of the dynamics, while the number of components in the Gaussian mixture corresponds to the number of cell classes.', 'Using back-propagation, we determine the minimum rank and number of cell classes needed to implement neuroscience tasks of increasing complexity.', 'We then exploit mean-field theory to reverse-engineer the obtained solutions and identify the respective roles of dimensionality and cell classes.', 'We show that the rank determines the phase-space available for dynamics that implement input-output mappings, while having multiple cell classes allows networks to flexibly switch between different types of dynamics in the available phase-space.', 'Our results have implications for the analysis of neuroscience experiments and the development of explainable AI.']
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SklZVQtLLr
['A theoretical analysis of a new class of RNNs, trained on neuroscience tasks, allows us to identify the role of dynamical dimensionality and cell classes in neural computations.']
The description of neural computations in the field of neuroscience relies on two competing views:, (i) a classical single-cell view that relates the activity of individual neurons to sensory or behavioural variables, and focuses on how different cell classes map onto computations;, (ii) a more recent population view that instead characterises computations in terms of collective neural trajectories, and focuses on the dimensionality of these trajectories as animals perform tasks., How the two key concepts of cell classes and low-dimensional trajectories interact to shape neural computations is however currently not understood., Here we address this question by combining machine-learning tools for training RNNs with reverse-engineering and theoretical analyses of network dynamics., We introduce a novel class of theoretically tractable recurrent networks: low-rank, mixture of Gaussian RNNs., In these networks, the rank of the connectivity controls the dimensionality of the dynamics, while the number of components in the Gaussian mixture corresponds to the number of cell classes., Using back-propagation, we determine the minimum rank and number of cell classes needed to implement neuroscience tasks of increasing complexity., We then exploit mean-field theory to reverse-engineer the obtained solutions and identify the respective roles of dimensionality and cell classes., We show that the rank determines the phase-space available for dynamics that implement input-output mappings, while having multiple cell classes allows networks to flexibly switch between different types of dynamics in the available phase-space., Our results have implications for the analysis of neuroscience experiments and the development of explainable AI.
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['We propose the fusion discriminator, a single unified framework for incorporating conditional information into a generative adversarial network (GAN) for a variety of distinct structured prediction tasks, including image synthesis, semantic segmentation, and depth estimation.', 'Much like commonly used convolutional neural network - conditional Markov random field (CNN-CRF) models, the proposed method is able to enforce higher-order consistency in the model, but without being limited to a very specific class of potentials.', 'The method is conceptually simple and flexible, and our experimental results demonstrate improvement on several diverse structured prediction tasks.']
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SJlf488Y_4
['We propose the fusion discriminator, a novel architecture for incorporating conditional information into the discriminator of GANs for structured prediction tasks.']
We propose the fusion discriminator, a single unified framework for incorporating conditional information into a generative adversarial network (GAN) for a variety of distinct structured prediction tasks, including image synthesis, semantic segmentation, and depth estimation., Much like commonly used convolutional neural network - conditional Markov random field (CNN-CRF) models, the proposed method is able to enforce higher-order consistency in the model, but without being limited to a very specific class of potentials., The method is conceptually simple and flexible, and our experimental results demonstrate improvement on several diverse structured prediction tasks.
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['Model-based reinforcement learning (MBRL) has been shown to be a powerful framework for data-efficiently learning control of continuous tasks.', 'Recent work in MBRL has mostly focused on using more advanced function approximators and planning schemes, leaving the general framework virtually unchanged since its conception.', 'In this paper, we identify a fundamental issue of the standard MBRL framework -- what we call the objective mismatch issue.', 'Objective mismatch arises when one objective is optimized in the hope that a second, often uncorrelated, metric will also be optimized.', 'In the context of MBRL, we characterize the objective mismatch between training the forward dynamics model w.r.t. the likelihood of the one-step ahead prediction, and the overall goal of improving performance on a downstream control task.', 'For example, this issue can emerge with the realization that dynamics models effective for a specific task do not necessarily need to be globally accurate, and vice versa globally accurate models might not be sufficiently accurate locally to obtain good control performance on a specific task.', 'In our experiments, we study this objective mismatch issue and demonstrate that the likelihood of the one-step ahead prediction is not always correlated with downstream control performance.', 'This observation highlights a critical flaw in the current MBRL framework which will require further research to be fully understood and addressed.', 'We propose an initial method to mitigate the mismatch issue by re-weighting dynamics model training.', 'Building on it, we conclude with a discussion about other potential directions of future research for addressing this issue.']
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Sked_0EYwB
['We define, explore, and begin to address the objective mismatch issue in model-based reinforcement learning.']
Model-based reinforcement learning (MBRL) has been shown to be a powerful framework for data-efficiently learning control of continuous tasks., Recent work in MBRL has mostly focused on using more advanced function approximators and planning schemes, leaving the general framework virtually unchanged since its conception., In this paper, we identify a fundamental issue of the standard MBRL framework -- what we call the objective mismatch issue., Objective mismatch arises when one objective is optimized in the hope that a second, often uncorrelated, metric will also be optimized., In the context of MBRL, we characterize the objective mismatch between training the forward dynamics model w.r.t. the likelihood of the one-step ahead prediction, and the overall goal of improving performance on a downstream control task., For example, this issue can emerge with the realization that dynamics models effective for a specific task do not necessarily need to be globally accurate, and vice versa globally accurate models might not be sufficiently accurate locally to obtain good control performance on a specific task., In our experiments, we study this objective mismatch issue and demonstrate that the likelihood of the one-step ahead prediction is not always correlated with downstream control performance., This observation highlights a critical flaw in the current MBRL framework which will require further research to be fully understood and addressed., We propose an initial method to mitigate the mismatch issue by re-weighting dynamics model training., Building on it, we conclude with a discussion about other potential directions of future research for addressing this issue.
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['There has recently been a heated debate (e.g. Schwartz-Ziv & Tishby (2017), Saxe et al. (2018), Noshad et al. (2018), Goldfeld et al. (2018)) about measuring the information flow in Deep Neural Networks using techniques from information theory.', 'It is claimed that Deep Neural Networks in general have good generalization capabilities since they not only learn how to map from an input to an output but also how to compress information about the training data input (Schwartz-Ziv & Tishby, 2017).', 'That is, they abstract the input information and strip down any unnecessary or over-specific information.', 'If so, the message compression method, Information Bottleneck (IB), could be used as a natural comparator for network performance, since this method gives an optimal information compression boundary.', 'This claim was then later denounced as well as reaffirmed (e.g. Saxe et al. (2018), Achille et al. (2017), Noshad et al. (2018)), as the employed method of mutual information measuring is not actually measuring information but clustering of the internal layer representations (Goldfeld et al. (2018)).', 'In this paper, we will present a detailed explanation of the development in the Information Plain (IP), which is a plot-type that compares mutual information to judge compression (Schwartz-Ziv & Tishby (2017)), when noise is retroactively added (using binning estimation). ', 'We also explain why different activation functions show different trajectories on the IP.', 'Further, we have looked into the effect of clustering on the network loss through early and perfect stopping using the Information Plane and how clustering can be used to help network pruning.']
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Hyljn1SFwr
['We give a detailed explanation of the trajectories in the information plane and investigate its usage for neural network design (pruning)']
There has recently been a heated debate (e.g. Schwartz-Ziv & Tishby (2017), Saxe et al. (2018), Noshad et al. (2018), Goldfeld et al. (2018)) about measuring the information flow in Deep Neural Networks using techniques from information theory., It is claimed that Deep Neural Networks in general have good generalization capabilities since they not only learn how to map from an input to an output but also how to compress information about the training data input (Schwartz-Ziv & Tishby, 2017)., That is, they abstract the input information and strip down any unnecessary or over-specific information., If so, the message compression method, Information Bottleneck (IB), could be used as a natural comparator for network performance, since this method gives an optimal information compression boundary., This claim was then later denounced as well as reaffirmed (e.g. Saxe et al. (2018), Achille et al. (2017), Noshad et al. (2018)), as the employed method of mutual information measuring is not actually measuring information but clustering of the internal layer representations (Goldfeld et al. (2018))., In this paper, we will present a detailed explanation of the development in the Information Plain (IP), which is a plot-type that compares mutual information to judge compression (Schwartz-Ziv & Tishby (2017)), when noise is retroactively added (using binning estimation). , We also explain why different activation functions show different trajectories on the IP., Further, we have looked into the effect of clustering on the network loss through early and perfect stopping using the Information Plane and how clustering can be used to help network pruning.
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["Formal understanding of the inductive bias behind deep convolutional networks, i.e. the relation between the network's architectural features and the functions it is able to model, is limited.", 'In this work, we establish a fundamental connection between the fields of quantum physics and deep learning, and use it for obtaining novel theoretical observations regarding the inductive bias of convolutional networks.', "Specifically, we show a structural equivalence between the function realized by a convolutional arithmetic circuit (ConvAC) and a quantum many-body wave function, which facilitates the use of quantum entanglement measures as quantifiers of a deep network's expressive ability to model correlations.", 'Furthermore, the construction of a deep ConvAC in terms of a quantum Tensor Network is enabled.', 'This allows us to perform a graph-theoretic analysis of a convolutional network, tying its expressiveness to a min-cut in its underlying graph.', 'We demonstrate a practical outcome in the form of a direct control over the inductive bias via the number of channels (width) of each layer.', 'We empirically validate our findings on standard convolutional networks which involve ReLU activations and max pooling.', 'The description of a deep convolutional network in well-defined graph-theoretic tools and the structural connection to quantum entanglement, are two interdisciplinary bridges that are brought forth by this work.']
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SywXXwJAb
["Employing quantum entanglement measures for quantifying correlations in deep learning, and using the connection to fit the deep network's architecture to correlations in the data."]
Formal understanding of the inductive bias behind deep convolutional networks, i.e. the relation between the network's architectural features and the functions it is able to model, is limited., In this work, we establish a fundamental connection between the fields of quantum physics and deep learning, and use it for obtaining novel theoretical observations regarding the inductive bias of convolutional networks., Specifically, we show a structural equivalence between the function realized by a convolutional arithmetic circuit (ConvAC) and a quantum many-body wave function, which facilitates the use of quantum entanglement measures as quantifiers of a deep network's expressive ability to model correlations., Furthermore, the construction of a deep ConvAC in terms of a quantum Tensor Network is enabled., This allows us to perform a graph-theoretic analysis of a convolutional network, tying its expressiveness to a min-cut in its underlying graph., We demonstrate a practical outcome in the form of a direct control over the inductive bias via the number of channels (width) of each layer., We empirically validate our findings on standard convolutional networks which involve ReLU activations and max pooling., The description of a deep convolutional network in well-defined graph-theoretic tools and the structural connection to quantum entanglement, are two interdisciplinary bridges that are brought forth by this work.
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['Deep learning algorithms are increasingly used in modeling chemical processes.', 'However, black box predictions without rationales have limited used in practical applications, such as drug design.', 'To this end, we learn to identify molecular substructures -- rationales -- that are associated with the target chemical property (e.g., toxicity).', 'The rationales are learned in an unsupervised fashion, requiring no additional information beyond the end-to-end task.', 'We formulate this problem as a reinforcement learning problem over the molecular graph, parametrized by two convolution networks corresponding to the rationale selection and prediction based on it, where the latter induces the reward function.', 'We evaluate the approach on two benchmark toxicity datasets.', 'We demonstrate that our model sustains high performance under the additional constraint that predictions strictly follow the rationales.', 'Additionally, we validate the extracted rationales through comparison against those described in chemical literature and through synthetic experiments.']
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HkJ1rgbCb
['We use a reinforcement learning over molecular graphs to generate rationales for interpretable molecular property prediction.']
Deep learning algorithms are increasingly used in modeling chemical processes., However, black box predictions without rationales have limited used in practical applications, such as drug design., To this end, we learn to identify molecular substructures -- rationales -- that are associated with the target chemical property (e.g., toxicity)., The rationales are learned in an unsupervised fashion, requiring no additional information beyond the end-to-end task., We formulate this problem as a reinforcement learning problem over the molecular graph, parametrized by two convolution networks corresponding to the rationale selection and prediction based on it, where the latter induces the reward function., We evaluate the approach on two benchmark toxicity datasets., We demonstrate that our model sustains high performance under the additional constraint that predictions strictly follow the rationales., Additionally, we validate the extracted rationales through comparison against those described in chemical literature and through synthetic experiments.
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['In recent years, substantial progress has been made on graph convolutional networks (GCN).', 'In this paper, for the first time, we theoretically analyze the connections between GCN and matrix factorization (MF), and unify GCN as matrix factorization with co-training and unitization.', 'Moreover, under the guidance of this theoretical analysis, we propose an alternative model to GCN named Co-training and Unitized Matrix Factorization (CUMF).', 'The correctness of our analysis is verified by thorough experiments.', 'The experimental results show that CUMF achieves similar or superior performances compared to GCN.', 'In addition, CUMF inherits the benefits of MF-based methods to naturally support constructing mini-batches, and is more friendly to distributed computing comparing with GCN.', 'The distributed CUMF on semi-supervised node classification significantly outperforms distributed GCN methods.', 'Thus, CUMF greatly benefits large scale and complex real-world applications.']
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[0.25, 0.3636363446712494, 0.060606054961681366, 0.0, 0.0, 0.05882352590560913, 0.0, 0.0952380895614624]
HJxf53EtDr
['We unify graph convolutional networks as co-training and unitized matrix factorization.']
In recent years, substantial progress has been made on graph convolutional networks (GCN)., In this paper, for the first time, we theoretically analyze the connections between GCN and matrix factorization (MF), and unify GCN as matrix factorization with co-training and unitization., Moreover, under the guidance of this theoretical analysis, we propose an alternative model to GCN named Co-training and Unitized Matrix Factorization (CUMF)., The correctness of our analysis is verified by thorough experiments., The experimental results show that CUMF achieves similar or superior performances compared to GCN., In addition, CUMF inherits the benefits of MF-based methods to naturally support constructing mini-batches, and is more friendly to distributed computing comparing with GCN., The distributed CUMF on semi-supervised node classification significantly outperforms distributed GCN methods., Thus, CUMF greatly benefits large scale and complex real-world applications.
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['Molecular graph generation is a fundamental problem for drug discovery and has been attracting growing attention.', 'The problem is challenging since it requires not only generating chemically valid molecular structures but also optimizing their chemical properties in the meantime.', 'Inspired by the recent progress in deep generative models, in this paper we propose a flow-based autoregressive model for graph generation called GraphAF.', 'GraphAF combines the advantages of both autoregressive and flow-based approaches and enjoys: (1) high model flexibility for data density estimation; (2) efficient parallel computation for training; (3) an iterative sampling process, which allows leveraging chemical domain knowledge for valency checking.', 'Experimental results show that GraphAF is able to generate 68\\% chemically valid molecules even without chemical knowledge rules and 100\\% valid molecules with chemical rules.', 'The training process of GraphAF is two times faster than the existing state-of-the-art approach GCPN.', 'After fine-tuning the model for goal-directed property optimization with reinforcement learning, GraphAF achieves state-of-the-art performance on both chemical property optimization and constrained property optimization.']
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S1esMkHYPr
['A flow-based autoregressive model for molecular graph generation. Reaching state-of-the-art results on molecule generation and properties optimization.']
Molecular graph generation is a fundamental problem for drug discovery and has been attracting growing attention., The problem is challenging since it requires not only generating chemically valid molecular structures but also optimizing their chemical properties in the meantime., Inspired by the recent progress in deep generative models, in this paper we propose a flow-based autoregressive model for graph generation called GraphAF., GraphAF combines the advantages of both autoregressive and flow-based approaches and enjoys: (1) high model flexibility for data density estimation; (2) efficient parallel computation for training; (3) an iterative sampling process, which allows leveraging chemical domain knowledge for valency checking., Experimental results show that GraphAF is able to generate 68\% chemically valid molecules even without chemical knowledge rules and 100\% valid molecules with chemical rules., The training process of GraphAF is two times faster than the existing state-of-the-art approach GCPN., After fine-tuning the model for goal-directed property optimization with reinforcement learning, GraphAF achieves state-of-the-art performance on both chemical property optimization and constrained property optimization.
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['We study two types of preconditioners and preconditioned stochastic gradient descent (SGD) methods in a unified framework.', 'We call the first one the Newton type due to its close relationship to the Newton method, and the second one the Fisher type as its preconditioner is closely related to the inverse of Fisher information matrix.', 'Both preconditioners can be derived from one framework, and efficiently estimated on any matrix Lie groups designated by the user using natural or relative gradient descent minimizing certain preconditioner estimation criteria.', 'Many existing preconditioners and methods, e.g., RMSProp, Adam, KFAC, equilibrated SGD, batch normalization, etc., are special cases of or closely related to either the Newton type or the Fisher type ones.', 'Experimental results on relatively large scale machine learning problems are reported for performance study.']
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[0.30434781312942505, 0.25925925374031067, 0.13333332538604736, 0.4067796468734741, 0.09302324801683426]
Bye5SiAqKX
['We propose a new framework for preconditioner learning, derive new forms of preconditioners and learning methods, and reveal the relationship to methods like RMSProp, Adam, Adagrad, ESGD, KFAC, batch normalization, etc.']
We study two types of preconditioners and preconditioned stochastic gradient descent (SGD) methods in a unified framework., We call the first one the Newton type due to its close relationship to the Newton method, and the second one the Fisher type as its preconditioner is closely related to the inverse of Fisher information matrix., Both preconditioners can be derived from one framework, and efficiently estimated on any matrix Lie groups designated by the user using natural or relative gradient descent minimizing certain preconditioner estimation criteria., Many existing preconditioners and methods, e.g., RMSProp, Adam, KFAC, equilibrated SGD, batch normalization, etc., are special cases of or closely related to either the Newton type or the Fisher type ones., Experimental results on relatively large scale machine learning problems are reported for performance study.
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['We present EDA: easy data augmentation techniques for boosting performance on text classification tasks.', 'EDA consists of four simple but powerful operations: synonym replacement, random insertion, random swap, and random deletion.', 'On five text classification tasks, we show that EDA improves performance for both convolutional and recurrent neural networks.', 'EDA demonstrates particularly strong results for smaller datasets; on average, across five datasets, training with EDA while using only 50% of the available training set achieved the same accuracy as normal training with all available data.', 'We also performed extensive ablation studies and suggest parameters for practical use.']
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[0.48275861144065857, 0.0, 0.3030303120613098, 0.08888888359069824, 0.07407406717538834]
BJelsDvo84
['Simple text augmentation techniques can significantly boost performance on text classification tasks, especially for small datasets.']
We present EDA: easy data augmentation techniques for boosting performance on text classification tasks., EDA consists of four simple but powerful operations: synonym replacement, random insertion, random swap, and random deletion., On five text classification tasks, we show that EDA improves performance for both convolutional and recurrent neural networks., EDA demonstrates particularly strong results for smaller datasets; on average, across five datasets, training with EDA while using only 50% of the available training set achieved the same accuracy as normal training with all available data., We also performed extensive ablation studies and suggest parameters for practical use.
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['We propose a model that is able to perform physical parameter estimation of systems from video, where the differential equations governing the scene dynamics are known, but labeled states or objects are not available.', 'Existing physical scene understanding methods require either object state supervision, or do not integrate with differentiable physics to learn interpretable system parameters and states.', 'We address this problem through a \\textit{physics-as-inverse-graphics} approach that brings together vision-as-inverse-graphics and differentiable physics engines, where objects and explicit state and velocity representations are discovered by the model.', 'This framework allows us to perform long term extrapolative video prediction, as well as vision-based model-predictive control.', 'Our approach significantly outperforms related unsupervised methods in long-term future frame prediction of systems with interacting objects (such as ball-spring or 3-body gravitational systems), due to its ability to build dynamics into the model as an inductive bias.', 'We further show the value of this tight vision-physics integration by demonstrating data-efficient learning of vision-actuated model-based control for a pendulum system.', "We also show that the controller's interpretability provides unique capabilities in goal-driven control and physical reasoning for zero-data adaptation."]
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BJeKwTNFvB
['We propose a model that is able to perform physical parameter estimation of systems from video, where the differential equations governing the scene dynamics are known, but labeled states or objects are not available.']
We propose a model that is able to perform physical parameter estimation of systems from video, where the differential equations governing the scene dynamics are known, but labeled states or objects are not available., Existing physical scene understanding methods require either object state supervision, or do not integrate with differentiable physics to learn interpretable system parameters and states., We address this problem through a \textit{physics-as-inverse-graphics} approach that brings together vision-as-inverse-graphics and differentiable physics engines, where objects and explicit state and velocity representations are discovered by the model., This framework allows us to perform long term extrapolative video prediction, as well as vision-based model-predictive control., Our approach significantly outperforms related unsupervised methods in long-term future frame prediction of systems with interacting objects (such as ball-spring or 3-body gravitational systems), due to its ability to build dynamics into the model as an inductive bias., We further show the value of this tight vision-physics integration by demonstrating data-efficient learning of vision-actuated model-based control for a pendulum system., We also show that the controller's interpretability provides unique capabilities in goal-driven control and physical reasoning for zero-data adaptation.
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['This paper proposes ASAL, a new pool based active learning method that generates high entropy samples.', 'Instead of directly annotating the synthetic samples, ASAL searches similar samples from the pool and includes them for training.', 'Hence, the quality of new samples is high and annotations are reliable. ', 'ASAL is particularly suitable for large data sets because it achieves a better run-time complexity (sub-linear) for sample selection than traditional uncertainty sampling (linear).', 'We present a comprehensive set of experiments on two data sets and show that ASAL outperforms similar methods and clearly exceeds the established baseline (random sampling). ', 'In the discussion section we analyze in which situations ASAL performs best and why it is sometimes hard to outperform random sample selection.', 'To the best of our knowledge this is the first adversarial active learning technique that is applied for multiple class problems using deep convolutional classifiers and demonstrates superior performance than random sample selection.']
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r1GB5jA5tm
['ASAL is a pool based active learning method that generates high entropy samples and retrieves matching samples from the pool in sub-linear time.']
This paper proposes ASAL, a new pool based active learning method that generates high entropy samples., Instead of directly annotating the synthetic samples, ASAL searches similar samples from the pool and includes them for training., Hence, the quality of new samples is high and annotations are reliable. , ASAL is particularly suitable for large data sets because it achieves a better run-time complexity (sub-linear) for sample selection than traditional uncertainty sampling (linear)., We present a comprehensive set of experiments on two data sets and show that ASAL outperforms similar methods and clearly exceeds the established baseline (random sampling). , In the discussion section we analyze in which situations ASAL performs best and why it is sometimes hard to outperform random sample selection., To the best of our knowledge this is the first adversarial active learning technique that is applied for multiple class problems using deep convolutional classifiers and demonstrates superior performance than random sample selection.
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['We point out important problems with the common practice of using the best single model performance for comparing deep learning architectures, and we propose a method that corrects these flaws.', 'Each time a model is trained, one gets a different result due to random factors in the training process, which include random parameter initialization and random data shuffling.', 'Reporting the best single model performance does not appropriately address this stochasticity.', 'We propose a normalized expected best-out-of-n performance (Boo_n) as a way to correct these problems.']
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Skx5txzb0W
['We point out important problems with the common practice of using the best single model performance for comparing deep learning architectures, and we propose a method that corrects these flaws.']
We point out important problems with the common practice of using the best single model performance for comparing deep learning architectures, and we propose a method that corrects these flaws., Each time a model is trained, one gets a different result due to random factors in the training process, which include random parameter initialization and random data shuffling., Reporting the best single model performance does not appropriately address this stochasticity., We propose a normalized expected best-out-of-n performance (Boo_n) as a way to correct these problems.
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['Unsupervised domain adaptation aims to generalize the hypothesis trained in a source domain to an unlabeled target domain.', 'One popular approach to this problem is to learn domain-invariant embeddings for both domains.', 'In this work, we study, theoretically and empirically, the effect of the embedding complexity on generalization to the target domain.', 'In particular, this complexity affects an upper bound on the target risk; this is reflected in experiments, too.', 'Next, we specify our theoretical framework to multilayer neural networks.', 'As a result, we develop a strategy that mitigates sensitivity to the embedding complexity, and empirically achieves performance on par with or better than the best layer-dependent complexity tradeoff.']
[0, 0, 0, 0, 0, 1]
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SkgOzlrKvH
['We study the effect of the embedding complexity in learning domain-invariant representations and develop a strategy that mitigates sensitivity to it.']
Unsupervised domain adaptation aims to generalize the hypothesis trained in a source domain to an unlabeled target domain., One popular approach to this problem is to learn domain-invariant embeddings for both domains., In this work, we study, theoretically and empirically, the effect of the embedding complexity on generalization to the target domain., In particular, this complexity affects an upper bound on the target risk; this is reflected in experiments, too., Next, we specify our theoretical framework to multilayer neural networks., As a result, we develop a strategy that mitigates sensitivity to the embedding complexity, and empirically achieves performance on par with or better than the best layer-dependent complexity tradeoff.
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['We propose a new architecture termed Dual Adversarial Transfer Network (DATNet) for addressing low-resource Named Entity Recognition (NER).', 'Specifically, two variants of DATNet, i.e., DATNet-F and DATNet-P, are proposed to explore effective feature fusion between high and low resource.', 'To address the noisy and imbalanced training data, we propose a novel Generalized Resource-Adversarial Discriminator (GRAD).', 'Additionally, adversarial training is adopted to boost model generalization.', 'We examine the effects of different components in DATNet across domains and languages and show that significant improvement can be obtained especially for low-resource data.', 'Without augmenting any additional hand-crafted features, we achieve new state-of-the-art performances on CoNLL and Twitter NER---88.16% F1 for Spanish, 53.43% F1 for WNUT-2016, and 42.83% F1 for WNUT-2017.']
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HkGzUjR5tQ
['We propose a new architecture termed Dual Adversarial Transfer Network (DATNet) for addressing low-resource Named Entity Recognition (NER) and achieve new state-of-the-art performances on CoNLL and Twitter NER.']
We propose a new architecture termed Dual Adversarial Transfer Network (DATNet) for addressing low-resource Named Entity Recognition (NER)., Specifically, two variants of DATNet, i.e., DATNet-F and DATNet-P, are proposed to explore effective feature fusion between high and low resource., To address the noisy and imbalanced training data, we propose a novel Generalized Resource-Adversarial Discriminator (GRAD)., Additionally, adversarial training is adopted to boost model generalization., We examine the effects of different components in DATNet across domains and languages and show that significant improvement can be obtained especially for low-resource data., Without augmenting any additional hand-crafted features, we achieve new state-of-the-art performances on CoNLL and Twitter NER---88.16% F1 for Spanish, 53.43% F1 for WNUT-2016, and 42.83% F1 for WNUT-2017.
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['Generative adversarial networks (GANs) evolved into one of the most successful unsupervised techniques for generating realistic images.', 'Even though it has recently been shown that GAN training converges, GAN models often end up in local Nash equilibria that are associated with mode collapse or otherwise fail to model the target distribution.', 'We introduce Coulomb GANs, which pose the GAN learning problem as a potential field, where generated samples are attracted to training set samples but repel each other.', 'The discriminator learns a potential field while the generator decreases the energy by moving its samples along the vector (force) field determined by the gradient of the potential field.', 'Through decreasing the energy, the GAN model learns to generate samples according to the whole target distribution and does not only cover some of its modes.', 'We prove that Coulomb GANs possess only one Nash equilibrium which is optimal in the sense that the model distribution equals the target distribution.', 'We show the efficacy of Coulomb GANs on LSUN bedrooms, CelebA faces, CIFAR-10 and the Google Billion Word text generation.']
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SkVqXOxCb
['Coulomb GANs can optimally learn a distribution by posing the distribution learning problem as optimizing a potential field']
Generative adversarial networks (GANs) evolved into one of the most successful unsupervised techniques for generating realistic images., Even though it has recently been shown that GAN training converges, GAN models often end up in local Nash equilibria that are associated with mode collapse or otherwise fail to model the target distribution., We introduce Coulomb GANs, which pose the GAN learning problem as a potential field, where generated samples are attracted to training set samples but repel each other., The discriminator learns a potential field while the generator decreases the energy by moving its samples along the vector (force) field determined by the gradient of the potential field., Through decreasing the energy, the GAN model learns to generate samples according to the whole target distribution and does not only cover some of its modes., We prove that Coulomb GANs possess only one Nash equilibrium which is optimal in the sense that the model distribution equals the target distribution., We show the efficacy of Coulomb GANs on LSUN bedrooms, CelebA faces, CIFAR-10 and the Google Billion Word text generation.
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['Predicting properties of nodes in a graph is an important problem with applications in a variety of domains.', 'Graph-based Semi Supervised Learning (SSL) methods aim to address this problem by labeling a small subset of the nodes as seeds, and then utilizing the graph structure to predict label scores for the rest of the nodes in the graph.', 'Recently, Graph Convolutional Networks (GCNs) have achieved impressive performance on the graph-based SSL task.', 'In addition to label scores, it is also desirable to have a confidence score associated with them.', 'Unfortunately, confidence estimation in the context of GCN has not been previously explored.', 'We fill this important gap in this paper and propose ConfGCN, which estimates labels scores along with their confidences jointly in GCN-based setting.', 'ConfGCN uses these estimated confidences to determine the influence of one node on another during neighborhood aggregation, thereby acquiring anisotropic capabilities.', 'Through extensive analysis and experiments on standard benchmarks, we find that ConfGCN is able to significantly outperform state-of-the-art baselines.', 'We have made ConfGCN’s source code available to encourage reproducible research.']
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[0.07692307233810425, 0.1395348757505417, 0.1599999964237213, 0.14814814925193787, 0.0833333283662796, 0.1249999925494194, 0.0, 0.0, 0.09090908616781235]
HklUN3RcFX
['We propose a confidence based Graph Convolutional Network for Semi-Supervised Learning.']
Predicting properties of nodes in a graph is an important problem with applications in a variety of domains., Graph-based Semi Supervised Learning (SSL) methods aim to address this problem by labeling a small subset of the nodes as seeds, and then utilizing the graph structure to predict label scores for the rest of the nodes in the graph., Recently, Graph Convolutional Networks (GCNs) have achieved impressive performance on the graph-based SSL task., In addition to label scores, it is also desirable to have a confidence score associated with them., Unfortunately, confidence estimation in the context of GCN has not been previously explored., We fill this important gap in this paper and propose ConfGCN, which estimates labels scores along with their confidences jointly in GCN-based setting., ConfGCN uses these estimated confidences to determine the influence of one node on another during neighborhood aggregation, thereby acquiring anisotropic capabilities., Through extensive analysis and experiments on standard benchmarks, we find that ConfGCN is able to significantly outperform state-of-the-art baselines., We have made ConfGCN’s source code available to encourage reproducible research.
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['In this paper we establish rigorous benchmarks for image classifier robustness.', 'Our first benchmark, ImageNet-C, standardizes and expands the corruption robustness topic, while showing which classifiers are preferable in safety-critical applications.', "Then we propose a new dataset called ImageNet-P which enables researchers to benchmark a classifier's robustness to common perturbations.", 'Unlike recent robustness research, this benchmark evaluates performance on common corruptions and perturbations not worst-case adversarial perturbations.', 'We find that there are negligible changes in relative corruption robustness from AlexNet classifiers to ResNet classifiers.', 'Afterward we discover ways to enhance corruption and perturbation robustness.', 'We even find that a bypassed adversarial defense provides substantial common perturbation robustness.', 'Together our benchmarks may aid future work toward networks that robustly generalize.']
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HJz6tiCqYm
['We propose ImageNet-C to measure classifier corruption robustness and ImageNet-P to measure perturbation robustness']
In this paper we establish rigorous benchmarks for image classifier robustness., Our first benchmark, ImageNet-C, standardizes and expands the corruption robustness topic, while showing which classifiers are preferable in safety-critical applications., Then we propose a new dataset called ImageNet-P which enables researchers to benchmark a classifier's robustness to common perturbations., Unlike recent robustness research, this benchmark evaluates performance on common corruptions and perturbations not worst-case adversarial perturbations., We find that there are negligible changes in relative corruption robustness from AlexNet classifiers to ResNet classifiers., Afterward we discover ways to enhance corruption and perturbation robustness., We even find that a bypassed adversarial defense provides substantial common perturbation robustness., Together our benchmarks may aid future work toward networks that robustly generalize.
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['The paper explores a novel methodology in source code obfuscation through the application of text-based recurrent neural network network (RNN) encoder-decoder models in ciphertext generation and key generation.', 'Sequence-to-sequence models\n', 'are incorporated into the model architecture to generate obfuscated code, generate the deobfuscation key, and live execution.', 'Quantitative benchmark comparison to existing obfuscation methods indicate significant improvement in stealth and execution cost for the proposed solution, and experiments regarding the model’s properties yield positive results regarding its character variation, dissimilarity to the original codebase, and consistent length of obfuscated code.']
[0, 1, 0, 0]
[0.2222222238779068, 0.23076923191547394, 0.1666666567325592]
SygQlT4FwS
['Obfuscate code using seq2seq networks, and execute using the obfuscated code and key pair']
The paper explores a novel methodology in source code obfuscation through the application of text-based recurrent neural network network (RNN) encoder-decoder models in ciphertext generation and key generation., Sequence-to-sequence models , are incorporated into the model architecture to generate obfuscated code, generate the deobfuscation key, and live execution., Quantitative benchmark comparison to existing obfuscation methods indicate significant improvement in stealth and execution cost for the proposed solution, and experiments regarding the model’s properties yield positive results regarding its character variation, dissimilarity to the original codebase, and consistent length of obfuscated code.
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['We propose a method for joint image and per-pixel annotation synthesis with GAN.', 'We demonstrate that GAN has good high-level representation of target data that can be easily projected to semantic segmentation masks.', 'This method can be used to create a training dataset for teaching separate semantic segmentation network.', 'Our experiments show that such segmentation network successfully generalizes on real data.', 'Additionally, the method outperforms supervised training when the number of training samples is small, and works on variety of different scenes and classes.', 'The source code of the proposed method will be publicly available.']
[1, 0, 0, 0, 0, 0]
[0.7272727489471436, 0.0, 0.1599999964237213, 0.0, 0.1428571343421936, 0.09999999403953552]
SJllFpVYwS
['GAN-based method for joint image and per-pixel annotation synthesis']
We propose a method for joint image and per-pixel annotation synthesis with GAN., We demonstrate that GAN has good high-level representation of target data that can be easily projected to semantic segmentation masks., This method can be used to create a training dataset for teaching separate semantic segmentation network., Our experiments show that such segmentation network successfully generalizes on real data., Additionally, the method outperforms supervised training when the number of training samples is small, and works on variety of different scenes and classes., The source code of the proposed method will be publicly available.
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['Vision-Language Navigation (VLN) is the task where an agent is commanded to navigate in photo-realistic unknown environments with natural language instructions.', 'Previous research on VLN is primarily conducted on the Room-to-Room (R2R) dataset with only English instructions. ', 'The ultimate goal of VLN, however, is to serve people speaking arbitrary languages.', 'Towards multilingual VLN with numerous languages, we collect a cross-lingual R2R dataset, which extends the original benchmark with corresponding Chinese instructions.', 'But it is time-consuming and expensive to collect large-scale human instructions for every existing language.', 'Based on the newly introduced dataset, we propose a general cross-lingual VLN framework to enable instruction-following navigation for different languages.', 'We first explore the possibility of building a cross-lingual agent when no training data of the target language is available.', 'The cross-lingual agent is equipped with a meta-learner to aggregate cross-lingual representations and a visually grounded cross-lingual alignment module to align textual representations of different languages.', 'Under the zero-shot learning scenario, our model shows competitive results even compared to a model trained with all target language instructions.', 'In addition, we introduce an adversarial domain adaption loss to improve the transferring ability of our model when given a certain amount of target language data.', 'Our methods and dataset demonstrate the potentials of building a cross-lingual agent to serve speakers with different languages.']
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[0.10810810327529907, 0.24242423474788666, 0.0, 0.21621620655059814, 0.1249999925494194, 0.4864864945411682, 0.22857142984867096, 0.15789473056793213, 0.10810810327529907, 0.1428571343421936, 0.2857142686843872]
rkeZO1BFDB
['We introduce a new task and dataset on cross-lingual vision-language navigation, and propose a general cross-lingual VLN framework for the task.']
Vision-Language Navigation (VLN) is the task where an agent is commanded to navigate in photo-realistic unknown environments with natural language instructions., Previous research on VLN is primarily conducted on the Room-to-Room (R2R) dataset with only English instructions. , The ultimate goal of VLN, however, is to serve people speaking arbitrary languages., Towards multilingual VLN with numerous languages, we collect a cross-lingual R2R dataset, which extends the original benchmark with corresponding Chinese instructions., But it is time-consuming and expensive to collect large-scale human instructions for every existing language., Based on the newly introduced dataset, we propose a general cross-lingual VLN framework to enable instruction-following navigation for different languages., We first explore the possibility of building a cross-lingual agent when no training data of the target language is available., The cross-lingual agent is equipped with a meta-learner to aggregate cross-lingual representations and a visually grounded cross-lingual alignment module to align textual representations of different languages., Under the zero-shot learning scenario, our model shows competitive results even compared to a model trained with all target language instructions., In addition, we introduce an adversarial domain adaption loss to improve the transferring ability of our model when given a certain amount of target language data., Our methods and dataset demonstrate the potentials of building a cross-lingual agent to serve speakers with different languages.
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['Deep generative models have advanced the state-of-the-art in semi-supervised classification, however their capacity for deriving useful discriminative features in a completely unsupervised fashion for classification in difficult real-world data sets, where adequate manifold separation is required has not been adequately explored.', 'Most methods rely on defining a pipeline of deriving features via generative modeling and then applying clustering algorithms, separating the modeling and discriminative processes.', 'We propose a deep hierarchical generative model which uses a mixture of discrete and continuous distributions to learn to effectively separate the different data manifolds and is trainable end-to-end.', "We show that by specifying the form of the discrete variable distribution we are imposing a specific structure on the model's latent representations.", "We test our model's discriminative performance on the task of CLL diagnosis against baselines from the field of computational FC, as well as the Variational Autoencoder literature."]
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ryb83alCZ
['Unsupervised classification via deep generative modeling with controllable feature learning evaluated in a difficult real world task']
Deep generative models have advanced the state-of-the-art in semi-supervised classification, however their capacity for deriving useful discriminative features in a completely unsupervised fashion for classification in difficult real-world data sets, where adequate manifold separation is required has not been adequately explored., Most methods rely on defining a pipeline of deriving features via generative modeling and then applying clustering algorithms, separating the modeling and discriminative processes., We propose a deep hierarchical generative model which uses a mixture of discrete and continuous distributions to learn to effectively separate the different data manifolds and is trainable end-to-end., We show that by specifying the form of the discrete variable distribution we are imposing a specific structure on the model's latent representations., We test our model's discriminative performance on the task of CLL diagnosis against baselines from the field of computational FC, as well as the Variational Autoencoder literature.
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['Representation Learning over graph structured data has received significant attention recently due to its ubiquitous applicability.', 'However, most advancements have been made in static graph settings while efforts for jointly learning dynamic of the graph and dynamic on the graph are still in an infant stage.', 'Two fundamental questions arise in learning over dynamic graphs:', '(i) How to elegantly model dynamical processes over graphs?', '(ii) How to leverage such a model to effectively encode evolving graph information into low-dimensional representations?', 'We present DyRep - a novel modeling framework for dynamic graphs that posits representation learning as a latent mediation process bridging two observed processes namely -- dynamics of the network (realized as topological evolution) and dynamics on the network (realized as activities between nodes).', 'Concretely, we propose a two-time scale deep temporal point process model that captures the interleaved dynamics of the observed processes.', 'This model is further parameterized by a temporal-attentive representation network that encodes temporally evolving structural information into node representations which in turn drives the nonlinear evolution of the observed graph dynamics.', 'Our unified framework is trained using an efficient unsupervised procedure and has capability to generalize over unseen nodes.', 'We demonstrate that DyRep outperforms state-of-the-art baselines for dynamic link prediction and time prediction tasks and present extensive qualitative insights into our framework.']
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HyePrhR5KX
['Models Representation Learning over dynamic graphs as latent hidden process bridging two observed processes of Topological Evolution of and Interactions on dynamic graphs.']
Representation Learning over graph structured data has received significant attention recently due to its ubiquitous applicability., However, most advancements have been made in static graph settings while efforts for jointly learning dynamic of the graph and dynamic on the graph are still in an infant stage., Two fundamental questions arise in learning over dynamic graphs:, (i) How to elegantly model dynamical processes over graphs?, (ii) How to leverage such a model to effectively encode evolving graph information into low-dimensional representations?, We present DyRep - a novel modeling framework for dynamic graphs that posits representation learning as a latent mediation process bridging two observed processes namely -- dynamics of the network (realized as topological evolution) and dynamics on the network (realized as activities between nodes)., Concretely, we propose a two-time scale deep temporal point process model that captures the interleaved dynamics of the observed processes., This model is further parameterized by a temporal-attentive representation network that encodes temporally evolving structural information into node representations which in turn drives the nonlinear evolution of the observed graph dynamics., Our unified framework is trained using an efficient unsupervised procedure and has capability to generalize over unseen nodes., We demonstrate that DyRep outperforms state-of-the-art baselines for dynamic link prediction and time prediction tasks and present extensive qualitative insights into our framework.
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['With the success of modern machine learning, it is becoming increasingly important to understand and control how learning algorithms interact.', 'Unfortunately, negative results from game theory show there is little hope of understanding or controlling general n-player games.', 'We therefore introduce smooth markets (SM-games), a class of n-player games with pairwise zero sum interactions.', 'SM-games codify a common design pattern in machine learning that includes some GANs, adversarial training, and other recent algorithms.', 'We show that SM-games are amenable to analysis and optimization using first-order methods.']
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B1xMEerYvB
['We introduce a class of n-player games suited to gradient-based methods.']
With the success of modern machine learning, it is becoming increasingly important to understand and control how learning algorithms interact., Unfortunately, negative results from game theory show there is little hope of understanding or controlling general n-player games., We therefore introduce smooth markets (SM-games), a class of n-player games with pairwise zero sum interactions., SM-games codify a common design pattern in machine learning that includes some GANs, adversarial training, and other recent algorithms., We show that SM-games are amenable to analysis and optimization using first-order methods.
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['While counter machines have received little attention in theoretical computer science since the 1960s, they have recently achieved a newfound relevance to the field of natural language processing (NLP).', 'Recent work has suggested that some strong-performing recurrent neural networks utilize their memory as counters.', 'Thus, one potential way to understand the sucess of these networks is to revisit the theory of counter computation.', 'Therefore, we choose to study the abilities of real-time counter machines as formal grammars.', 'We first show that several variants of the counter machine converge to express the same class of formal languages.', 'We also prove that counter languages are closed under complement, union, intersection, and many other common set operations.', 'Next, we show that counter machines cannot evaluate boolean expressions, even though they can weakly validate their syntax.', 'This has implications for the interpretability and evaluation of neural network systems: successfully matching syntactic patterns does not guarantee that a counter-like model accurately represents underlying semantic structures.', 'Finally, we consider the question of whether counter languages are semilinear.', 'This work makes general contributions to the theory of formal languages that are of particular interest for the interpretability of recurrent neural networks.']
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rylMgCNYvS
['We study the class of formal languages acceptable by real-time counter automata, a model of computation related to some types of recurrent neural networks.']
While counter machines have received little attention in theoretical computer science since the 1960s, they have recently achieved a newfound relevance to the field of natural language processing (NLP)., Recent work has suggested that some strong-performing recurrent neural networks utilize their memory as counters., Thus, one potential way to understand the sucess of these networks is to revisit the theory of counter computation., Therefore, we choose to study the abilities of real-time counter machines as formal grammars., We first show that several variants of the counter machine converge to express the same class of formal languages., We also prove that counter languages are closed under complement, union, intersection, and many other common set operations., Next, we show that counter machines cannot evaluate boolean expressions, even though they can weakly validate their syntax., This has implications for the interpretability and evaluation of neural network systems: successfully matching syntactic patterns does not guarantee that a counter-like model accurately represents underlying semantic structures., Finally, we consider the question of whether counter languages are semilinear., This work makes general contributions to the theory of formal languages that are of particular interest for the interpretability of recurrent neural networks.
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['Attentional, RNN-based encoder-decoder models for abstractive summarization have achieved good performance on short input and output sequences.', 'For longer documents and summaries however these models often include repetitive and incoherent phrases.', 'We introduce a neural network model with a novel intra-attention that attends over the input and continuously generated output separately, and a new training method that combines standard supervised word prediction and reinforcement learning (RL). \n', 'Models trained only with supervised learning often exhibit "exposure bias" - they assume ground truth is provided at each step during training.\n', 'However, when standard word prediction is combined with the global sequence prediction training of RL the resulting summaries become more readable.\n', 'We evaluate this model on the CNN/Daily Mail and New York Times datasets.', 'Our model obtains a 41.16 ROUGE-1 score on the CNN/Daily Mail dataset, an improvement over previous state-of-the-art models.', 'Human evaluation also shows that our model produces higher quality summaries.']
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HkAClQgA-
['A summarization model combining a new intra-attention and reinforcement learning method to increase summary ROUGE scores and quality for long sequences.']
Attentional, RNN-based encoder-decoder models for abstractive summarization have achieved good performance on short input and output sequences., For longer documents and summaries however these models often include repetitive and incoherent phrases., We introduce a neural network model with a novel intra-attention that attends over the input and continuously generated output separately, and a new training method that combines standard supervised word prediction and reinforcement learning (RL). , Models trained only with supervised learning often exhibit "exposure bias" - they assume ground truth is provided at each step during training. , However, when standard word prediction is combined with the global sequence prediction training of RL the resulting summaries become more readable. , We evaluate this model on the CNN/Daily Mail and New York Times datasets., Our model obtains a 41.16 ROUGE-1 score on the CNN/Daily Mail dataset, an improvement over previous state-of-the-art models., Human evaluation also shows that our model produces higher quality summaries.
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["Knowledge Distillation (KD) is a common method for transferring the ``knowledge'' learned by one machine learning model (the teacher) into another model (the student), where typically, the teacher has a greater capacity (e.g., more parameters or higher bit-widths).", "To our knowledge, existing methods overlook the fact that although the student absorbs extra knowledge from the teacher, both models share the same input data -- and this data is the only medium by which the teacher's knowledge can be demonstrated.", 'Due to the difference in model capacities, the student may not benefit fully from the same data points on which the teacher is trained.', 'On the other hand, a human teacher may demonstrate a piece of knowledge with individualized examples adapted to a particular student, for instance, in terms of her cultural background and interests.', 'Inspired by this behavior, we design data augmentation agents with distinct roles to facilitate knowledge distillation.', 'Our data augmentation agents generate distinct training data for the teacher and student, respectively.', 'We focus specifically on KD when the teacher network has greater precision (bit-width) than the student network.\n\n', "We find empirically that specially tailored data points enable the teacher's knowledge to be demonstrated more effectively to the student.", 'We compare our approach with existing KD methods on training popular neural architectures and demonstrate that role-wise data augmentation improves the effectiveness of KD over strong prior approaches.', 'The code for reproducing our results will be made publicly available.']
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rJeidA4KvS
['We study whether and how adaptive data augmentation and knowledge distillation can be leveraged simultaneously in a synergistic manner for better training student networks.']
Knowledge Distillation (KD) is a common method for transferring the ``knowledge'' learned by one machine learning model (the teacher) into another model (the student), where typically, the teacher has a greater capacity (e.g., more parameters or higher bit-widths)., To our knowledge, existing methods overlook the fact that although the student absorbs extra knowledge from the teacher, both models share the same input data -- and this data is the only medium by which the teacher's knowledge can be demonstrated., Due to the difference in model capacities, the student may not benefit fully from the same data points on which the teacher is trained., On the other hand, a human teacher may demonstrate a piece of knowledge with individualized examples adapted to a particular student, for instance, in terms of her cultural background and interests., Inspired by this behavior, we design data augmentation agents with distinct roles to facilitate knowledge distillation., Our data augmentation agents generate distinct training data for the teacher and student, respectively., We focus specifically on KD when the teacher network has greater precision (bit-width) than the student network. , We find empirically that specially tailored data points enable the teacher's knowledge to be demonstrated more effectively to the student., We compare our approach with existing KD methods on training popular neural architectures and demonstrate that role-wise data augmentation improves the effectiveness of KD over strong prior approaches., The code for reproducing our results will be made publicly available.
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['Neural network models have shown excellent fluency and performance when applied to abstractive summarization.', 'Many approaches to neural abstractive summarization involve the introduction of significant inductive bias, such as pointer-generator architectures, coverage, and partially extractive procedures, designed to mimic human summarization.', 'We show that it is possible to attain competitive performance by instead directly viewing summarization as language modeling.', 'We introduce a simple procedure built upon pre-trained decoder-transformers to obtain competitive ROUGE scores using a language modeling loss alone, with no beam-search or other decoding-time optimization, and instead rely on efficient nucleus sampling and greedy decoding.']
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BJx5zpc58r
['We introduce a simple procedure to repurpose pre-trained transformer-based language models to perform abstractive summarization well.']
Neural network models have shown excellent fluency and performance when applied to abstractive summarization., Many approaches to neural abstractive summarization involve the introduction of significant inductive bias, such as pointer-generator architectures, coverage, and partially extractive procedures, designed to mimic human summarization., We show that it is possible to attain competitive performance by instead directly viewing summarization as language modeling., We introduce a simple procedure built upon pre-trained decoder-transformers to obtain competitive ROUGE scores using a language modeling loss alone, with no beam-search or other decoding-time optimization, and instead rely on efficient nucleus sampling and greedy decoding.
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['This paper addresses the problem of incremental domain adaptation (IDA).', 'We assume each domain comes sequentially, and that we could only access data in the current domain.', 'The goal of IDA is to build a unified model performing well on all the encountered domains.', 'We propose to augment a recurrent neural network (RNN) with a directly parameterized memory bank, which is retrieved by an attention mechanism at each step of RNN transition.', 'The memory bank provides a natural way of IDA: when adapting our model to a new domain, we progressively add new slots to the memory bank, which increases the model capacity.', 'We learn the new memory slots and fine-tune existing parameters by back-propagation. \n', 'Experiments show that our approach significantly outperforms naive fine-tuning and previous work on IDA, including elastic weight consolidation and the progressive neural network. ', 'Compared with expanding hidden states, our approach is more robust for old domains, shown by both empirical and theoretical results.']
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rJgkE5HsnV
['We present a neural memory-based architecture for incremental domain adaptation, and provide theoretical and empirical results.']
This paper addresses the problem of incremental domain adaptation (IDA)., We assume each domain comes sequentially, and that we could only access data in the current domain., The goal of IDA is to build a unified model performing well on all the encountered domains., We propose to augment a recurrent neural network (RNN) with a directly parameterized memory bank, which is retrieved by an attention mechanism at each step of RNN transition., The memory bank provides a natural way of IDA: when adapting our model to a new domain, we progressively add new slots to the memory bank, which increases the model capacity., We learn the new memory slots and fine-tune existing parameters by back-propagation. , Experiments show that our approach significantly outperforms naive fine-tuning and previous work on IDA, including elastic weight consolidation and the progressive neural network. , Compared with expanding hidden states, our approach is more robust for old domains, shown by both empirical and theoretical results.
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['In compressed sensing, a primary problem to solve is to reconstruct a high dimensional sparse signal from a small number of observations.', 'In this work, we develop a new sparse signal recovery algorithm using reinforcement learning (RL) and Monte CarloTree Search (MCTS).', 'Similarly to orthogonal matching pursuit (OMP), our RL+MCTS algorithm chooses the support of the signal sequentially.', 'The key novelty is that the proposed algorithm learns how to choose the next support as opposed to following a pre-designed rule as in OMP.', 'Empirical results are provided to demonstrate the superior performance of the proposed RL+MCTS algorithm over existing sparse signal recovery algorithms.']
[0, 1, 0, 0, 0]
[0.21739129722118378, 0.2978723347187042, 0.2380952388048172, 0.2857142686843872, 0.260869562625885]
Sygfa739LS
['Formulating sparse signal recovery as a sequential decision making problem, we develop a method based on RL and MCTS that learns a policy to discover the support of the sparse signal. ']
In compressed sensing, a primary problem to solve is to reconstruct a high dimensional sparse signal from a small number of observations., In this work, we develop a new sparse signal recovery algorithm using reinforcement learning (RL) and Monte CarloTree Search (MCTS)., Similarly to orthogonal matching pursuit (OMP), our RL+MCTS algorithm chooses the support of the signal sequentially., The key novelty is that the proposed algorithm learns how to choose the next support as opposed to following a pre-designed rule as in OMP., Empirical results are provided to demonstrate the superior performance of the proposed RL+MCTS algorithm over existing sparse signal recovery algorithms.
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['Many real-world sequential decision-making problems can be formulated as optimal control with high-dimensional observations and unknown dynamics.', 'A promising approach is to embed the high-dimensional observations into a lower-dimensional latent representation space, estimate the latent dynamics model, then utilize this model for control in the latent space.', 'An important open question is how to learn a representation that is amenable to existing control algorithms?', 'In this paper, we focus on learning representations for locally-linear control algorithms, such as iterative LQR (iLQR).', 'By formulating and analyzing the representation learning problem from an optimal control perspective, we establish three underlying principles that the learned representation should comprise: 1) accurate prediction in the observation space, 2) consistency between latent and observation space dynamics, and 3) low curvature in the latent space transitions.', 'These principles naturally correspond to a loss function that consists of three terms: prediction, consistency, and curvature (PCC).', 'Crucially, to make PCC tractable, we derive an amortized variational bound for the PCC loss function.', 'Extensive experiments on benchmark domains demonstrate that the new variational-PCC learning algorithm benefits from significantly more stable and reproducible training, and leads to superior control performance. ', 'Further ablation studies give support to the importance of all three PCC components for learning a good latent space for control.']
[1, 0, 0, 0, 0, 0, 0, 0, 0]
[0.3333333432674408, 0.24242423474788666, 0.09090908616781235, 0.1666666567325592, 0.04444444179534912, 0.0, 0.09090908616781235, 0.060606058686971664, 0.14814814925193787]
BJxG_0EtDS
['Learning embedding for control with high-dimensional observations']
Many real-world sequential decision-making problems can be formulated as optimal control with high-dimensional observations and unknown dynamics., A promising approach is to embed the high-dimensional observations into a lower-dimensional latent representation space, estimate the latent dynamics model, then utilize this model for control in the latent space., An important open question is how to learn a representation that is amenable to existing control algorithms?, In this paper, we focus on learning representations for locally-linear control algorithms, such as iterative LQR (iLQR)., By formulating and analyzing the representation learning problem from an optimal control perspective, we establish three underlying principles that the learned representation should comprise: 1) accurate prediction in the observation space, 2) consistency between latent and observation space dynamics, and 3) low curvature in the latent space transitions., These principles naturally correspond to a loss function that consists of three terms: prediction, consistency, and curvature (PCC)., Crucially, to make PCC tractable, we derive an amortized variational bound for the PCC loss function., Extensive experiments on benchmark domains demonstrate that the new variational-PCC learning algorithm benefits from significantly more stable and reproducible training, and leads to superior control performance. , Further ablation studies give support to the importance of all three PCC components for learning a good latent space for control.
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['The interplay between inter-neuronal network topology and cognition has been studied deeply by connectomics researchers and network scientists, which is crucial towards understanding the remarkable efficacy of biological neural networks.', 'Curiously, the deep learning revolution that revived neural networks has not paid much attention to topological aspects.', 'The architectures of deep neural networks (DNNs) do not resemble their biological counterparts in the topological sense.', 'We bridge this gap by presenting initial results of Deep Connectomics Networks (DCNs) as DNNs with topologies inspired by real-world neuronal networks.', 'We show high classification accuracy obtained by DCNs whose architecture was inspired by the biological neuronal networks of C. Elegans and the mouse visual cortex.']
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BJg6EmYL8B
['Initial findings in the intersection of network neuroscience and deep learning. C. Elegans and a mouse visual cortex learn to recognize handwritten digits.']
The interplay between inter-neuronal network topology and cognition has been studied deeply by connectomics researchers and network scientists, which is crucial towards understanding the remarkable efficacy of biological neural networks., Curiously, the deep learning revolution that revived neural networks has not paid much attention to topological aspects., The architectures of deep neural networks (DNNs) do not resemble their biological counterparts in the topological sense., We bridge this gap by presenting initial results of Deep Connectomics Networks (DCNs) as DNNs with topologies inspired by real-world neuronal networks., We show high classification accuracy obtained by DCNs whose architecture was inspired by the biological neuronal networks of C. Elegans and the mouse visual cortex.
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['Convolutional neural networks and recurrent neural networks are designed with network structures well suited to the nature of spacial and sequential data respectively.', 'However, the structure of standard feed-forward neural networks (FNNs) is simply a stack of fully connected layers, regardless of the feature correlations in data.', 'In addition, the number of layers and the number of neurons are manually tuned on validation data, which is time-consuming and may lead to suboptimal networks.', 'In this paper, we propose an unsupervised structure learning method for learning parsimonious deep FNNs.', 'Our method determines the number of layers, the number of neurons at each layer, and the sparse connectivity between adjacent layers automatically from data.', 'The resulting models are called Backbone-Skippath Neural Networks (BSNNs).', 'Experiments on 17 tasks show that, in comparison with FNNs, BSNNs can achieve better or comparable classification performance with much fewer parameters.', 'The interpretability of BSNNs is also shown to be better than that of FNNs.']
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HJMN-xWC-
['An unsupervised structure learning method for Parsimonious Deep Feed-forward Networks.']
Convolutional neural networks and recurrent neural networks are designed with network structures well suited to the nature of spacial and sequential data respectively., However, the structure of standard feed-forward neural networks (FNNs) is simply a stack of fully connected layers, regardless of the feature correlations in data., In addition, the number of layers and the number of neurons are manually tuned on validation data, which is time-consuming and may lead to suboptimal networks., In this paper, we propose an unsupervised structure learning method for learning parsimonious deep FNNs., Our method determines the number of layers, the number of neurons at each layer, and the sparse connectivity between adjacent layers automatically from data., The resulting models are called Backbone-Skippath Neural Networks (BSNNs)., Experiments on 17 tasks show that, in comparison with FNNs, BSNNs can achieve better or comparable classification performance with much fewer parameters., The interpretability of BSNNs is also shown to be better than that of FNNs.
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['Bayesian inference is used extensively to infer and to quantify the uncertainty in a field of interest from a measurement of a related field when the two are linked by a mathematical model.', 'Despite its many applications, Bayesian inference faces challenges when inferring fields that have discrete representations of large dimension, and/or have prior distributions that are difficult to characterize mathematically.', 'In this work we demonstrate how the approximate distribution learned by a generative adversarial network (GAN) may be used as a prior in a Bayesian update to address both these challenges.', 'We demonstrate the efficacy of this approach by inferring and quantifying uncertainty in a physics-based inverse problem and an inverse problem arising in computer vision.', 'In this latter example, we also demonstrate how the knowledge of the spatial variation of uncertainty may be used to select an optimal strategy of placing the sensors (i.e. taking measurements), where information about the image is revealed one sub-region at a time.']
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HJlL2Q2qLS
['Using GANs as priors for efficient Bayesian inference of complex fields.']
Bayesian inference is used extensively to infer and to quantify the uncertainty in a field of interest from a measurement of a related field when the two are linked by a mathematical model., Despite its many applications, Bayesian inference faces challenges when inferring fields that have discrete representations of large dimension, and/or have prior distributions that are difficult to characterize mathematically., In this work we demonstrate how the approximate distribution learned by a generative adversarial network (GAN) may be used as a prior in a Bayesian update to address both these challenges., We demonstrate the efficacy of this approach by inferring and quantifying uncertainty in a physics-based inverse problem and an inverse problem arising in computer vision., In this latter example, we also demonstrate how the knowledge of the spatial variation of uncertainty may be used to select an optimal strategy of placing the sensors (i.e. taking measurements), where information about the image is revealed one sub-region at a time.
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['We argue that the widely used Omniglot and miniImageNet benchmarks are too simple because their class semantics do not vary across episodes, which defeats their intended purpose of evaluating few-shot classification methods.', 'The class semantics of Omniglot is invariably “characters” and the class semantics of miniImageNet, “object category”.', 'Because the class semantics are so similar, we propose a new method called Centroid Networks which can achieve surprisingly high accuracies on Omniglot and miniImageNet without using any labels at metaevaluation time.', 'Our results suggest that those benchmarks are not adapted for supervised few-shot classification since the supervision itself is not necessary during meta-evaluation.', 'The Meta-Dataset, a collection of 10 datasets, was recently proposed as a harder few-shot classification benchmark.', 'Using our method, we derive a new metric, the Class Semantics Consistency Criterion, and use it to quantify the difficulty of Meta-Dataset.', 'Finally, under some restrictive assumptions, we show that Centroid Networks is faster and more accurate than a state-of-the-art learning-to-cluster method (Hsu et al., 2018).']
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SygeY1SYvr
['Omniglot and miniImageNet are too simple for few-shot learning because we can solve them without using labels during meta-evaluation, as demonstrated with a method called centroid networks']
We argue that the widely used Omniglot and miniImageNet benchmarks are too simple because their class semantics do not vary across episodes, which defeats their intended purpose of evaluating few-shot classification methods., The class semantics of Omniglot is invariably “characters” and the class semantics of miniImageNet, “object category”., Because the class semantics are so similar, we propose a new method called Centroid Networks which can achieve surprisingly high accuracies on Omniglot and miniImageNet without using any labels at metaevaluation time., Our results suggest that those benchmarks are not adapted for supervised few-shot classification since the supervision itself is not necessary during meta-evaluation., The Meta-Dataset, a collection of 10 datasets, was recently proposed as a harder few-shot classification benchmark., Using our method, we derive a new metric, the Class Semantics Consistency Criterion, and use it to quantify the difficulty of Meta-Dataset., Finally, under some restrictive assumptions, we show that Centroid Networks is faster and more accurate than a state-of-the-art learning-to-cluster method (Hsu et al., 2018).
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['We learn to identify decision states, namely the parsimonious set of states where decisions meaningfully affect the future states an agent can reach in an environment.', 'We utilize the VIC framework, which maximizes an agent’s `empowerment’, ie the ability to reliably reach a diverse set of states -- and formulate a sandwich bound on the empowerment objective that allows identification of decision states. Unlike previous work, our decision states are discovered without extrinsic rewards -- simply by interacting with the world.', 'Our results show that our decision states are:', '1) often interpretable, and', '2) lead to better exploration on downstream goal-driven tasks in partially observable environments.']
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SJeQGJrKwH
['Identify decision states (where agent can take actions that matter) without reward supervision, use it for transfer.']
We learn to identify decision states, namely the parsimonious set of states where decisions meaningfully affect the future states an agent can reach in an environment., We utilize the VIC framework, which maximizes an agent’s `empowerment’, ie the ability to reliably reach a diverse set of states -- and formulate a sandwich bound on the empowerment objective that allows identification of decision states. Unlike previous work, our decision states are discovered without extrinsic rewards -- simply by interacting with the world., Our results show that our decision states are:, 1) often interpretable, and, 2) lead to better exploration on downstream goal-driven tasks in partially observable environments.
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['Inverse problems are ubiquitous in natural sciences and refer to the challenging task of inferring complex and potentially multi-modal posterior distributions over hidden parameters given a set of observations.', 'Typically, a model of the physical process in the form of differential equations is available but leads to intractable inference over its parameters.', 'While the forward propagation of parameters through the model simulates the evolution of the system, the inverse problem of finding the parameters given the sequence of states is not unique.', 'In this work, we propose a generalisation of the Bayesian optimisation framework to approximate inference.', 'The resulting method learns approximations to the posterior distribution by applying Stein variational gradient descent on top of estimates from a Gaussian process model.', "Preliminary results demonstrate the method's performance on likelihood-free inference for reinforcement learning environments."]
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HJxvcJhVYS
['An approach to combine variational inference and Bayesian optimisation to solve complicated inverse problems']
Inverse problems are ubiquitous in natural sciences and refer to the challenging task of inferring complex and potentially multi-modal posterior distributions over hidden parameters given a set of observations., Typically, a model of the physical process in the form of differential equations is available but leads to intractable inference over its parameters., While the forward propagation of parameters through the model simulates the evolution of the system, the inverse problem of finding the parameters given the sequence of states is not unique., In this work, we propose a generalisation of the Bayesian optimisation framework to approximate inference., The resulting method learns approximations to the posterior distribution by applying Stein variational gradient descent on top of estimates from a Gaussian process model., Preliminary results demonstrate the method's performance on likelihood-free inference for reinforcement learning environments.
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