inverse autoregressive flow
Improved Variational Inference with Inverse Autoregressive Flow
Durk P. Kingma, Tim Salimans, Rafal Jozefowicz, Xi Chen, Ilya Sutskever, Max Welling
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.
Improved Variational Inference with Inverse Autoregressive Flow
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.
Improved Variational Inference with Inverse Autoregressive Flow
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.
Reviews: Improving Variational Autoencoders with Inverse Autoregressive Flow
The idea is interesting, particularly in its approach to enable parallel computation on GPUs by whitening the data. This seems like a practical approach to choosing the family of transformations in the normalizing flows framework. Its novelty is low based on whitening, and being a simple extension to just one of many approaches for building expressive variational families. The experiments are lacking in comparison to the slew of recent approaches to expressive approximating families for variational inference. It mostly compares to non-variational inference based approaches and traditional approaches (e.g., diagonal Gaussians). For example, how does it compare to planar or radial flows as in the original paper?
Improved Variational Inference with Inverse Autoregressive Flow
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.
Improved Variational Inference with Inverse Autoregressive Flow
Kingma, Durk P., Salimans, Tim, Jozefowicz, Rafal, Chen, Xi, Sutskever, Ilya, Welling, Max
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.
Variational Bridge Constructs for Grey Box Modelling with Gaussian Processes
Ward, Wil O. C., Ryder, Tom, Prangle, Dennis, รlvarez, Mauricio A.
This paper introduces a method for inference of heterogeneous dynamical systems where part of the dynamics are known, in the form of an ordinary differential equation (ODEs), with some functional input that is unknown. Inference of such systems can be difficult, particularly when the dynamics are non-linear and the input is unknown. In this work, we place a Gaussian process (GP) prior over the input function which results in a stochastic It\^o process. Using an autoregressive variational approach, we simulate samples from the resulting process and conform them to the dynamics of the system, conditioned on some observation model. We apply the approach to non-linear ODEs to evaluate the method. As a simulation-based inference method, we also show how it can be extended to models with non-Gaussian likelihoods, such as count data.
ClariNet: Parallel Wave Generation in End-to-End Text-to-Speech
Ping, Wei, Peng, Kainan, Chen, Jitong
In this work, we propose an alternative solution for parallel wave generation by WaveNet. In contrast to parallel WaveNet (Oord et al., 2018), we distill a Gaussian inverse autoregressive flow from the autoregressive WaveNet by minimizing a novel regularized KL divergence between their highly-peaked output distributions. Our method computes the KL divergence in closed-form, which simplifies the training algorithm and provides very efficient distillation. In addition, we propose the first text-to-wave neural architecture for speech synthesis, which is fully convolutional and enables fast end-to-end training from scratch. It significantly outperforms the previous pipeline that connects a text-to-spectrogram model to a separately trained WaveNet (Ping et al., 2018). We also successfully distill a parallel waveform synthesizer conditioned on the hidden representation in this end-to-end model.
Improved Variational Inference with Inverse Autoregressive Flow
Kingma, Durk P., Salimans, Tim, Jozefowicz, Rafal, Chen, Xi, Sutskever, Ilya, Welling, Max
The framework of normalizing flows provides a general strategy for flexible variational inference of posteriors over latent variables. We propose a new type of normalizing flow, inverse autoregressive flow (IAF), that, in contrast to earlier published flows, scales well to high-dimensional latent spaces. The proposed flow consists of a chain of invertible transformations, where each transformation is based on an autoregressive neural network. In experiments, we show that IAF significantly improves upon diagonal Gaussian approximate posteriors. In addition, we demonstrate that a novel type of variational autoencoder, coupled with IAF, is competitive with neural autoregressive models in terms of attained log-likelihood on natural images, while allowing significantly faster synthesis.