CausalX: Causal Explanations and Block Multilinear Factor Analysis
- URL: http://arxiv.org/abs/2102.12853v2
- Date: Sat, 27 Feb 2021 12:03:44 GMT
- Title: CausalX: Causal Explanations and Block Multilinear Factor Analysis
- Authors: M. Alex O. Vasilescu, Eric Kim, and Xiao S. Zeng
- Abstract summary: We propose a unified multilinear model of wholes and parts.
We introduce an incremental bottom-up computational alternative, the Incremental M-mode Block SVD.
The resulting object representation is an interpretable choice of intrinsic causal factor representations related to an object's hierarchy of wholes and parts.
- Score: 3.087360758008569
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: By adhering to the dictum, "No causation without manipulation (treatment,
intervention)", cause and effect data analysis represents changes in observed
data in terms of changes in the causal factors. When causal factors are not
amenable for active manipulation in the real world due to current technological
limitations or ethical considerations, a counterfactual approach performs an
intervention on the model of data formation. In the case of object
representation or activity (temporal object) representation, varying object
parts is generally unfeasible whether they be spatial and/or temporal.
Multilinear algebra, the algebra of higher-order tensors, is a suitable and
transparent framework for disentangling the causal factors of data formation.
Learning a part-based intrinsic causal factor representations in a multilinear
framework requires applying a set of interventions on a part-based multilinear
model. We propose a unified multilinear model of wholes and parts. We derive a
hierarchical block multilinear factorization, the M-mode Block SVD, that
computes a disentangled representation of the causal factors by optimizing
simultaneously across the entire object hierarchy. Given computational
efficiency considerations, we introduce an incremental bottom-up computational
alternative, the Incremental M-mode Block SVD, that employs the lower-level
abstractions, the part representations, to represent the higher level of
abstractions, the parent wholes. This incremental computational approach may
also be employed to update the causal model parameters when data becomes
available incrementally. The resulting object representation is an
interpretable combinatorial choice of intrinsic causal factor representations
related to an object's recursive hierarchy of wholes and parts that renders
object recognition robust to occlusion and reduces training data requirements.
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