Volatility Based Kernels and Moving Average Means for Accurate Forecasting with Gaussian Processes

Add code
Jul 13, 2022
Gregory Benton, Wesley J. Maddox, Andrew Gordon Wilson
Figure 1 for Volatility Based Kernels and Moving Average Means for Accurate Forecasting with Gaussian Processes
Figure 2 for Volatility Based Kernels and Moving Average Means for Accurate Forecasting with Gaussian Processes
Figure 3 for Volatility Based Kernels and Moving Average Means for Accurate Forecasting with Gaussian Processes
Figure 4 for Volatility Based Kernels and Moving Average Means for Accurate Forecasting with Gaussian Processes

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon

A broad class of stochastic volatility models are defined by systems of stochastic differential equations. While these models have seen widespread success in domains such as finance and statistical climatology, they typically lack an ability to condition on historical data to produce a true posterior distribution. To address this fundamental limitation, we show how to re-cast a class of stochastic volatility models as a hierarchical Gaussian process (GP) model with specialized covariance functions. This GP model retains the inductive biases of the stochastic volatility model while providing the posterior predictive distribution given by GP inference. Within this framework, we take inspiration from well studied domains to introduce a new class of models, Volt and Magpie, that significantly outperform baselines in stock and wind speed forecasting, and naturally extend to the multitask setting.

* ICML 2022. Code available at https://github.com/g-benton/Volt  
View paper onarxiv icon

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon