Towards Learning in Grey Spatiotemporal Systems: A Prophet to
Non-consecutive Spatiotemporal Dynamics
- URL: http://arxiv.org/abs/2208.08878v1
- Date: Wed, 17 Aug 2022 14:59:48 GMT
- Title: Towards Learning in Grey Spatiotemporal Systems: A Prophet to
Non-consecutive Spatiotemporal Dynamics
- Authors: Zhengyang Zhou, Yang Kuo, Wei Sun, Binwu Wang, Min Zhou, Yunan Zong,
Yang Wang
- Abstract summary: We propose a Factor-Decoupled learning framework for Grey Stemporal Systems (G2S)
The core idea is to hierarchical decouple multi-level factors and enable both flexible aggregations and disentangled uncertainty estimations.
A Disangled Quantification is put forward to identify two types of uncertainty for reliability guarantees and model interpretations.
- Score: 8.028527069935732
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Spatiotemporal forecasting is an imperative topic in data science due to its
diverse and critical applications in smart cities. Existing works mostly
perform consecutive predictions of following steps with observations completely
and continuously obtained, where nearest observations can be exploited as key
knowledge for instantaneous status estimation. However, the practical issues of
early activity planning and sensor failures elicit a brand-new task, i.e.,
non-consecutive forecasting. In this paper, we define spatiotemporal learning
systems with missing observation as Grey Spatiotemporal Systems (G2S) and
propose a Factor-Decoupled learning framework for G2S (FDG2S), where the core
idea is to hierarchically decouple multi-level factors and enable both flexible
aggregations and disentangled uncertainty estimations. Firstly, to compensate
for missing observations, a generic semantic-neighboring sequence sampling is
devised, which selects representative sequences to capture both periodical
regularity and instantaneous variations. Secondly, we turn the predictions of
non-consecutive statuses into inferring statuses under expected combined
exogenous factors. In particular, a factor-decoupled aggregation scheme is
proposed to decouple factor-induced predictive intensity and region-wise
proximity by two energy functions of conditional random field. To infer
region-wise proximity under flexible factor-wise combinations and enable
dynamic neighborhood aggregations, we further disentangle compounded influences
of exogenous factors on region-wise proximity and learn to aggregate them.
Given the inherent incompleteness and critical applications of G2S, a
DisEntangled Uncertainty Quantification is put forward, to identify two types
of uncertainty for reliability guarantees and model interpretations.
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