Causality detection

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The determination of a causal interaction between fluctuating variables in a complex system, such as a fusion-grade plasma, is not straightforward.

Definition of causality

To start with, it is not even easy to define what causality means exactly. ^[1]^[2] In philosophy, causality typically refers to a relation between two events X and Y such that:

if Y occurs, then X will occur; or
if X occurs, then Y must have occured.

Thus, causality typically involves at least a temporal delay between the two events.

In the context of data analysis, it is more productive to adopt Wiener's 'quantifiable causality'. ^[3] It states:

if we can predict X better by using the past information from Y than without it, then we call Y causal to X.

Traditional approaches

Traditional approaches to the determination of causal relationships between various (fluctuating) variables include a wide range of methods.

If intervention in the system is possible, one may control (modulate) one variable and observe the (delayed) effect on other variables.
Observe systematic time delays between characteristic events or observe systematic precursors to characteristic events.
Predict the system evolution from a (numerical) model. If successful, the model equations may reveal causal relations.
Quantify parameters related to system evolution (growth rates, damping rates).
Use techniques such as correlations, conditional averages; these linear analysis techniques by themselves cannot reveal causality, but additional reasoning (based on physical insight or models) may allow drawing conclusions.

In the fusion context, see ^[4].

Analysis techniques

Several techniques have been elaborated to quantify Wiener's causality on the basis of measured time series. ^[5]

Recently, a specific technique taken from Information Theory (the Transfer Entropy)^[6] was applied succesfully to fluctuation data from fusion devices. ^[7]

References

↑ Causality
↑ Causality_(physics)
↑ N. Wiener. The theory of prediction. Modern Mathematics for Engineers, Mc-Graw Hill, New York, 1956, ISBN 0486497461
↑ K.H. Burrell, Tests of causality: Experimental evidence that sheared $E\times B$ flow alters turbulence and transport in tokamaks, Phys. Plasmas, 6(12):4418, 1999
↑ K. Hlaváková-Schindler, M. Palus, M. Vejmelka, and J. Bhattacharya. Causality detection based on information-theoretic approaches in time series analysis, Phys. Reports, 441(1):1, 2007
↑ T. Schreiber, Measuring information transfer, Phys. Rev. Lett., 85(2):461, 2000
↑ B.Ph. van Milligen, G. Birkenmeier, M. Ramisch, T. Estrada, C. Hidalgo, and A. Alonso, Causality detection and turbulence in fusion plasmas, Nucl. Fusion 54 (2014), 023011

[1] Causality

[2] Causality_(physics)

[3] N. Wiener. The theory of prediction. Modern Mathematics for Engineers, Mc-Graw Hill, New York, 1956, ISBN 0486497461

[4] K.H. Burrell, Tests of causality: Experimental evidence that sheared $E\times B$ flow alters turbulence and transport in tokamaks, Phys. Plasmas, 6(12):4418, 1999

[5] K. Hlaváková-Schindler, M. Palus, M. Vejmelka, and J. Bhattacharya. Causality detection based on information-theoretic approaches in time series analysis, Phys. Reports, 441(1):1, 2007

[6] T. Schreiber, Measuring information transfer, Phys. Rev. Lett., 85(2):461, 2000

[7] B.Ph. van Milligen, G. Birkenmeier, M. Ramisch, T. Estrada, C. Hidalgo, and A. Alonso, Causality detection and turbulence in fusion plasmas, Nucl. Fusion 54 (2014), 023011

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Causality detection

Contents

Definition of causality

Traditional approaches

Analysis techniques

References

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Causality detection

Definition of causality

Traditional approaches

Analysis techniques

References

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