Neurally-Guided Procedural Models: Amortized Inference for Procedural Graphics Programs using Neural Networks

Daniel Ritchie; Anna Thomas; Pat Hanrahan; Noah Goodman

2016 NIPS NeurIPS 2016

Neurally-Guided Procedural Models: Amortized Inference for Procedural Graphics Programs using Neural Networks

Abstract

Probabilistic inference algorithms such as Sequential Monte Carlo (SMC) provide powerful tools for constraining procedural models in computer graphics, but they require many samples to produce desirable results. In this paper, we show how to create procedural models which learn how to satisfy constraints. We augment procedural models with neural networks which control how the model makes random choices based on the output it has generated thus far. We call such models neurally-guided procedural models. As a pre-computation, we train these models to maximize the likelihood of example outputs generated via SMC. They are then used as efficient SMC importance samplers, generating high-quality results with very few samples. We evaluate our method on L-system-like models with image-based constraints. Given a desired quality threshold, neurally-guided models can generate satisfactory results up to 10x faster than unguided models.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Computer Science and Deep Learning and Machine Learning

📈 Trend Setter — Procedural Generation

🧭 Keyword Pioneer — procedural model

🐣 Hot Topic Early Bird — importance sampling

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Daniel Ritchie , Anna Thomas , Pat Hanrahan , Noah Goodman

Topics

Artificial Intelligence > Core AI > Procedural Generation Artificial Intelligence > Bayesian & Probabilistic > Probabilistic Modeling Machine Learning > Learning Types > Self-Supervised Learning Deep Learning > Models > Generative Models Computer Science > Applications > Computer Graphics

Keywords

probabilistic inference importance sampling sequential monte carlo amortized inference neural network procedural model graphics program

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