Information Theoretic Causal Effect Quantification

Wieczorek, Aleksander; Röth, Volker

doi:10.3390/e21100975

Cited by 9 publications

(9 citation statements)

References 69 publications

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“…The effect of a cause has been quantified using information theory (Wieczorek and Roth 2019), however, without considering learning in a Bayesian setting. Entropic causal inference (see (Compton et al 2021)) specifies circumstances where the causal direction between categorical variables can be determined from observational data under assumptions of limited entropy.…”

Section: Related Workmentioning

confidence: 99%

Probability trees and the value of a single intervention

Herlau¹

2022

Preprint

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The most fundamental problem in statistical causality is determining causal relationships from limited data. Probability trees, which combine prior causal structures with Bayesian updates, have been suggested as a possible solution. In this work, we quantify the information gain from a single intervention and show that both the anticipated information gain, prior to making an intervention, and the expected gain from an intervention have simple expressions. This results in an active-learning method that simply selects the intervention with the highest anticipated gain, which we illustrate through several examples. Our work demonstrates how probability trees, and Bayesian estimation of their parameters, offer a simple yet viable approach to fast causal induction.

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Section: Related Workmentioning

confidence: 99%

Probability trees and the value of a single intervention

Herlau¹

2022

Preprint

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“…Parents’ heights are potential causes of offspring heights, but not vice versa. This intuitively appealing idea leads to tests for predictive causality , such as classical Granger causality testing in time-series analysis and its nonparametric generalization to transfer entropy [ 19 ]. In these tests, X is defined as a predictive cause of Y if future values of Y are not conditionally independent of past and present values of X , given past and present values of Y itself.…”

Section: The Structure Of Explanations In Causal Bayesian Network (Bns)mentioning

confidence: 99%

“…Specifically, to predict how changing X (via an exogenous intervention or manipulation) would change the distribution of one of its descendants, Y , it is necessary to identify an adjustment set of other variables to condition upon [ 30 ]. Adjustment sets generalize the principle that one must condition on any common parents of X and Y to eliminate confounding biases, but must not condition on any common children to avoid introducing selection biases [ 19 ]. Appropriate adjustment sets can be computed from the DAG structure of a causal BN for both direct causal effects and total causal effects [ 30 ].…”

Section: The Structure Of Explanations In Causal Bayesian Network (Bns)mentioning

confidence: 99%

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Information Structures for Causally Explainable Decisions

Cox

2021

Entropy

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For an AI agent to make trustworthy decision recommendations under uncertainty on behalf of human principals, it should be able to explain why its recommended decisions make preferred outcomes more likely and what risks they entail. Such rationales use causal models to link potential courses of action to resulting outcome probabilities. They reflect an understanding of possible actions, preferred outcomes, the effects of action on outcome probabilities, and acceptable risks and trade-offs—the standard ingredients of normative theories of decision-making under uncertainty, such as expected utility theory. Competent AI advisory systems should also notice changes that might affect a user’s plans and goals. In response, they should apply both learned patterns for quick response (analogous to fast, intuitive “System 1” decision-making in human psychology) and also slower causal inference and simulation, decision optimization, and planning algorithms (analogous to deliberative “System 2” decision-making in human psychology) to decide how best to respond to changing conditions. Concepts of conditional independence, conditional probability tables (CPTs) or models, causality, heuristic search for optimal plans, uncertainty reduction, and value of information (VoI) provide a rich, principled framework for recognizing and responding to relevant changes and features of decision problems via both learned and calculated responses. This paper reviews how these and related concepts can be used to identify probabilistic causal dependencies among variables, detect changes that matter for achieving goals, represent them efficiently to support responses on multiple time scales, and evaluate and update causal models and plans in light of new data. The resulting causally explainable decisions make efficient use of available information to achieve goals in uncertain environments.

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“…Our approach combines two ideas: First, we make use of the ability of probability trees to represent context-dependent relationships by representing the different causal hypothesis as sub-trees in a single large probability tree, thereby reducing the problem of causal induction to a simple inference problem in this larger probability tree, which can be solved using Bayes theorem; second, by combining the causal hypotheses in a single model, we can predict the information gain associated with each intervention in advance, and thus select the intervention which has the highest gain, thereby leading to a natural activelearning method for causal induction on probability trees 1 . a) Related work: Information theory has previously been used to quantify the causal effect between variables [17], or to specify circumstances where the causal orientation of categorical variables can be determined from observational data [18]. Information geometry was used to infer causal orientation from observational data, using assumptions on generative mechanisms [19], however both settings are different from the Bayesian learning problem considered here.…”

Section: Introductionmentioning

confidence: 99%

Active learning of causal probability trees

Herlau¹

2022

Preprint

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The past two decades have seen a growing interest in combining causal information, commonly represented using causal graphs, with machine learning models. Probability trees provide a simple yet powerful alternative representation of causal information. They enable both computation of intervention and counterfactuals, and are strictly more general, since they allow context-dependent causal dependencies. Here we present a Bayesian method for learning probability trees from a combination of interventional and observational data. The method quantifies the expected information gain from an intervention, and selects the interventions with the largest gain. We demonstrate the efficiency of the method on simulated and real data. An effective method for learning probability trees on a limited interventional budget will greatly expand their applicability.

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Information Theoretic Causal Effect Quantification

Cited by 9 publications

References 69 publications

Probability trees and the value of a single intervention

Probability trees and the value of a single intervention

Information Structures for Causally Explainable Decisions

Active learning of causal probability trees

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