causality

In computer science, causality plays a major role in two ways: on the one hand, as a subsequent statement about which events led to which other events. This is particularly important when communicating in distributed systems with several senders and receivers, for example to ensure that instructions are carried out in the correct order, even if messages overtake each other in the network. Logical clocks are used for this purpose , which allow the causal order of events to be determined on the basis of time stamps .

• causa formalis : the cause of the shape (e.g. why does a saw chop wood? Because of the shape of the saw blade - the functional shape defines the essence of the saw)
• causa finalis : the ultimate cause (what is the purpose of sawing? to extract firewood)
• causa materialis : the cause of the material (Why is the saw made of metal? It must be hard enough to shred wood)
• causa efficiens : the effective cause (Why does the saw move? Because someone moves it)

In Hellenism the interest in causal events shifts from theoretical to practical questions. According to Epicurus , the aim of research into causes is to take away people's unrest caused by incomprehensible phenomena. In contrast to Aristotle, Zeno of Kition and the Stoa only recognize the active cause. For them, the cause is always a body that affects others. There are causes (Latin: causa continens ) that set long chains of effects in motion and can maintain them permanently.

Example: A sinner receives confession. We have: Causa formalis are the words of absolution (“Ego te absolvo a peccatis tuis in nomine Patris et Filii et Spiritus Sancti”). Causa materialis proxima , more detailed cause, are penitential acts or the resolution to do them (“pray to Our Father and a Creed ”), and the creed as such. Causa materialis remota , more distant, are the sins to be forgiven. Causa efficiens primaria , the first effective cause, is Jesus Christ in a divine and human nature. (His holy humanity is not listed as a causa instrumentalis, that would not be entirely wrong, but a little nestorianizing.) Causa efficiens secundaria , second, is the priest. Causa finalis primaria is (as always) the external glorification of God. Causa finalis secundaria is the salvation of the penitent. Causa meritoria , cause of merit, is Christ's work of redemption. Causa instrumentalis , instrumental cause, is sanctifying grace which is restored through the sacrament. Causa dispositiva , i.e. a necessary condition, is the power to confess, which the priest must have received from a legally competent superior, usually his bishop.

Materialism / Mechanicism

Materialistic and mechanistic philosophies, which were particularly widespread in France in the 18th century, ultimately attributed all causes to mechanical pressure and impact ("dance of atoms"). There were similar ideas with Democritus in antiquity . Approaches to overcoming the purely mechanical concept of cause can be found in Ludwig Feuerbach , who at least doubts that phenomena of higher forms of movement (i.e. life, thought, history) can be reduced to mechanics.

Immanuel Kant

Immanuel Kant distinguished from the "causality according to the laws of nature " a "causality through freedom :"

In contrast to Hume, Kant sees causality as a necessity. He argues that the causal thought belongs to the inner structure of knowledge if every particular causal rule comes from experience, because otherwise one would not be able to understand the world at all. For Kant, the proof of the necessity of causality lies in the logical and chronological sequence of time. He makes this clear in the Critique of Pure Reason using the example of the observation of a ball and an indentation in a pillow. Here there is only one logical conclusion from the ball as the cause to the indentation as the effect. The opposite conclusion would be absurd. (Example from the second analogy of experience: the principle of chronological order according to the law of causality) "The physics has largely confirmed the Kantian definition of causality and added as a postulate in its main theories." In the special theory of relativity of Einstein , although one Time dilation , but does not allow a time reversal, the causality remains in the sense of the temporal sequence. Likewise, the concept of chance in quantum theory is not violated.

On the one hand you have to have a certainty of your own thoughts that they are present in your own mind (self-confidence). On the other hand, not all concepts of one's own mind can come from pure experience, because otherwise one would not be able to categorize the impressions one receives. So you have to presuppose terms in order to be able to form ideas from sensory impressions. And to these a priori concepts, Kant also included the concept of causality. Causality is therefore not a thought content formed from impressions only constructed in retrospect, but the possibility of gaining experience at all presupposes the concept of causality, so it is necessary in order to be able to experience it in the first place. Otherwise we would only gain sensory impressions and not have the ability to construct meaningful and categorical contexts of experience. Like a toddler looking into a kaleidoscope, we would not be able to put the world together and would only look at the play of light in the kaleidoscope in amazement and remain awestruck by the play of light.

This objective world can be explored by the natural sciences, and we also assume a priori that certain regularities apply in it, which also seems to include the law of causality. The things for themselves remain hidden from us, because they lie outside of our human experience. We can only make reasonable guesses about them, since they underlie the phenomenal world in an unknowable way. According to Kant, this includes B. the idea of ​​God, the idea of ​​freedom and that of the immortal soul. There the limit of our reasonably possible knowledge is reached.

Criticism of the concept of causality

According to Ernst Mach, there are neither real causes nor causal relationships in nature, but only functional relationships. In conditionalism , the causes are replaced by conditions. John Stuart Mill already considered the full sum of its conditions to be the cause of a thing. Max Verworn increased this view into the absolute: the concept of cause is a holdover from pre-scientific ideas; every event is not caused, but merely conditioned by the totality of an infinite number of equivalent conditions.

Conception in dialectical materialism

In dialectical materialism in the official form of real existing socialism, internal contradictions of the objects and the new qualities appearing in the course of development are assumed. With every change, development of material things, processes, systems, etc. a. in nature and in society external and internal causes work together. External causes are called the interactions between all things, processes, and systems resulting from the universal connection; as internal causes of dialectic materialism referred to it according to all material things, processes, systems and. a. immanent contradictions that cause their movement, change and development. External and internal causes form a “dialectical unity”: the internal causes only become effective through the existence of the external, the external causes only through the mediation of the internal. The relationship between external and internal causes is relative: what is internal cause for one system can be external cause for another system and vice versa.

Modern approaches

John Leslie Mackie introduced the INUS condition to identify causes: an event is perceived as the cause of an outcome if it is an insufficient (Necessary) part of a condition that is not itself necessary (Unnecessary) Sufficient for the result.

The Closest World concept by David Lewis is now widely accepted based on a general definition of causality. David Lewis puts the counterfactual conditional operator in the center of the considerations and he gives as an example: "If kangaroos had no tails, they would fall over".

A world with tailless kangaroos is obviously against the facts. So we have to imagine a world that deviates from reality at least in this one point. Otherwise, this “parallel world” must be largely coherent and resemble our world as much as possible. Otherwise kangaroos could also live in this world who walk on crutches and therefore do not fall over.

In Causality , Judea Pearl shows how the closest world concept can be concretized.

How are counterfactual implication and causality related? The fact that the stone was thrown as the cause of the broken pane can be expressed as follows: If I hadn't thrown the stone, the pane would not have cracked. So we have to move on to the counterfactual implication of the negations: “Don't throw a stone” counterfactually implies “The pane won't break”.

An approach that best captures what is intuitively perceived as the reason was developed by Leonard Talmy . In cognitive semantics , the category of force dynamics he introduced is used to examine linguistic expressions for the force relationships on which the situations described are based. For the first time, the theory allows a finer distinction between the various causality relationships that exist in language for example. B. through the verbs cause , help , allow , enable , prevent , prevent , depend (on) etc. are expressed. But the semantics of causality-indicating conjunctions and prepositions such as because , though , despite can be analyzed. A multitude of psychic forces, which are expressed, for example, by forcing , persuading , resisting , are also the subject of the theory. In order for there to be a reason, there must be two opposing forces, an agent (agonist) and an opponent (antagonist). The following applies to them (in the case of a basic relationship): The agonist has an intrinsic tendency to be active, the antagonist an opposite tendency to be lazy. The agonist's power is greater than that of the antagonist. It has also been suggested (Phillip Wollf) that the type of causality in the force dynamic model is determined by three dimensions, (1) the tendency of the antagonist to result, (2) the force opposition between the units involved and (3) the (non- ) Occurrence of the result.

Determinism and Free Will

The philosophical consequences of causality are particularly interesting in connection with the philosophical line of thought of determinism . There it is assumed that each event is firmly predetermined by previous events, i.e. the universe develops as a causal chain . This applies to all levels, including the elementary particles of energy and matter . Since the human brain also consists of matter, it would also have to behave deterministically , i.e. in a way that can be theoretically calculated and predetermined.

Jurisprudence

Biology and behavioral research

If our ancestors ascribed the black and yellow stripes (effect) flashing behind the bushes to a tiger (cause) and ran away, they were well advised. The quick decision as to what could be the cause of the observation and the resulting action were life sustaining. The causality expectation on which this behavior is based belongs to the “innate teachers” ( Konrad Lorenz ): The “hypothesis of the cause” contains the “expectation that the same thing will have the same cause. This is initially nothing more than a judgment in advance. But this prejudice proves its worth ... in such an excess of cases that it is superior to any judgment that is different in principle or the waiver of judgment "( Rupert Riedl , 1981 )

Innate teachers have a downside: they can be thought traps : “Biological knowledge contains a system of sensible hypotheses, advance judgments, which guide us with the greatest wisdom within the framework of what they have been selected for; but lead us completely and wickedly astray at its limits ”(Rupert Riedl). The expectation of causality goes back to the fact that the pilot, captain or train driver is often prematurely blamed for an accident.

Social sciences

The extensive research on conditioning made many contributions to the understanding of the causality idea . Beginning with Thorndike's cat experiments on Pavlov's accidental discovery of classical conditioning and Skinner's operant conditioning , numerous laws were and are discovered under which conditions the idea of ​​a cause-and-effect relationship arises. The evolutionary origin of the idea of ​​causality is probably the need to identify reliable predictors for vital events.

1. Covariance : Changes in the assumed cause ( independent variable , UV) must be systematically related to changes in the assumed effect ( dependent variable , AV). So if z. B. Changes in the psychological treatment take place, it must be possible to observe these manipulations in the result, in the psychological symptoms.
2. Time sequence: The cause (UV) must take place before the effect (AV).
3. No alternative explanations: the assumed cause must be the only plausible explanation for the effect.

It is obvious that the third condition is the most difficult condition to realize. In a social science experiment / experimental design , mostly for ethical reasons, not all factors that could have an influence on the effect can be controlled, so a causal relationship can never be assumed with absolute certainty. Cross-sectional studies with third-party variable control and panel studies are helpful .

The social psychology considered phenomenal causality , the trend in social cognition , attributable to perceptible objects cause-effect relationships (so-called. Causal attribution ), which often lead together with value judgments about these objects in significant differences in the perception results.

In the therapy of learning disorders, Dieter Betz (in: Teufelskreis Lernstören, Psychologie Verlags Union, Munich-Weinheim 1987; not to be confused with the geologist of the same name) favors the effect structure as a network of very different causes, which must be made manageable if therapy has an effect as an intervention : "Anyone who works on the symptom in isolation risks a pedagogical vicious circle." Betz sees the conflict structure analysis ( KSA) as the basis for this work of the therapist .

statistics

With the statistics Although a relationship between two can events / variables are detected, but no causality. If one can prove a connection (a correlation ) between events A and B, then there are several possible explanations:

• A could cause B.
• B could cause A.
• A and B could be caused by a third event C (see also spurious correlation ).
• The relationship in the data could be erroneous or accidental; H. in truth not even exist.

Evidence of a statistical connection ( correlation ) is often misinterpreted as causality. Causality can only be inferred from a statistical correlation through additional information that was not obtained by means of statistics . An example that is only half jokingly meant is the decline in the birth rate and the decline in the stork population in western Germany at the end of the 1960s. From the fact that both developments occurred at the same time and to about the same extent, it cannot be concluded that the storks have anything to do with the number of newborn babies.

However, causalities can be included as a prerequisite; z. B. Regression analysis looks at independent ( ) and dependent variables ( ). It is assumed that the independent variables ( ) act on the dependent variables ( ). However, whether a variable is an independent or a dependent variable is determined by definition and not derived from statistical means. ${\ displaystyle X}$${\ displaystyle Y}$${\ displaystyle X}$${\ displaystyle Y}$

A causal relationship could be formulated that cannot be read as a statistical relationship ( causality without correlation ): A random generator is switched between a switch that lights up an incandescent lamp , which can (but does not have to ) convert the switching signal into its opposite. . Knowing the circuit, it is then clear that the position of the switch has an influence on whether the lamp is on at a certain point in time or not. The effect of this influence, however, is neither predictable nor statistically demonstrable. If the circuit was not known, it would not be apparent that there is any influence at all.

Econometrics (Granger)

In some areas of econometrics one is content with a z. B. Compared to philosophy, restricted concept of causality. In this case, the temporal order of the variables is in the foreground. The concept of causality in econometrics was decisively shaped by Clive WJ Granger . This works on the premise that the past determines the future and not the other way around. It says that a variable X for Y Granger-causality is when until the time for a given amount of information t-1 at time t , the variable Y can be better predicted than without the inclusion of the variables X . The Granger causality may apply in one direction or in both directions ( feedback - system ). The concept of causality is closely related to another theoretical concept of econometrics or time series analysis , exogeneity .

Granger causality is statistically testable. For this, consider a bivariate VAR (p) model :

${\ displaystyle {\ begin {pmatrix} Y_ {1t} \\ Y_ {2t} \ end {pmatrix}} = {\ begin {pmatrix} a_ {1} \\ a_ {2} \ end {pmatrix}} + { \ begin {pmatrix} \ phi _ {11.1} & \ phi _ {12.1} \\\ phi _ {21.1} & \ phi _ {22.1} \ end {pmatrix}} {\ begin {pmatrix} Y_ {1, t-1} \\ Y_ {2, t-1} \ end {pmatrix}} + \ dots + {\ begin {pmatrix} \ phi _ {11, p} & \ phi _ { 12, p} \\\ phi _ {21, p} & \ phi _ {22, p} \ end {pmatrix}} {\ begin {pmatrix} Y_ {1, tp} \\ Y_ {2, tp} \ end {pmatrix}} + {\ begin {pmatrix} Z_ {1t} \\ Z_ {2t} \ end {pmatrix}}}$

There is no Granger causality for on if: ${\ displaystyle Y_ {2}}$${\ displaystyle Y_ {1}}$

${\ displaystyle \ phi _ {12.1} = \ phi _ {12.2} = \ dots = \ phi _ {12, p} = 0}$

${\ displaystyle Y_ {1}}$is non-Granger-causal if: ${\ displaystyle Y_ {2}}$

${\ displaystyle \ phi _ {21.1} = \ phi _ {21.2} = \ dots = \ phi _ {21, p} = 0}$

The test for non-Granger causality thus corresponds to a test for zero restrictions for certain coefficients . The test statistic of such a test could look like this with normal white noise :

${\ displaystyle F (p, Nnp) = {\ frac {{\ text {RSS}} _ {r} - {\ text {RSS}} _ {u}} {p {\ hat {\ sigma}} _ { 11} ^ {2}}}}$

It is

• ${\ displaystyle N}$ the scope of the two time series
• ${\ displaystyle n}$the number of coefficients used in least squares estimation so that the number of degrees of freedom becomes smaller,
• ${\ displaystyle p}$the number of additional coefficients with which the variable X is included in the least squares estimation,
• ${\ displaystyle {\ text {RSS}} _ {r}}$the sum of the squared residuals of the least squares estimate of the equation with restrictions,
• ${\ displaystyle {\ text {RSS}} _ {u}}$the sum of the squared residuals of a least squares estimate of the equation without restrictions,
• ${\ displaystyle {\ hat {\ sigma}} _ {11} ^ {2} = {\ frac {{\ text {RSS}} _ {u}} {Nnp}}}$as the estimated variance of , where${\ displaystyle Z_ {1}}$
• ${\ displaystyle {\ hat {\ sigma}} _ {11}}$the standard deviation .

With the determined value of F one goes into the corresponding table of F in order to read off the probability that there is no Granger causality. It should be noted that only the (generally) lower probability of applies. The likelihood of is greater (in general) and not applicable. ${\ displaystyle F (p, Nnp)}$${\ displaystyle F (Nnp, p)}$

Business administration

A cost allocation principle is a procedure for converting costs to reference values. If, for example, a product unit is selected as the reference value, the costs of this unit can be calculated depending on the allocation principle used. This gives the unit cost.

Causality in medicine

The etiology (from ancient Greek αἰτία "cause" and λόγος "reason, doctrine") denotes the doctrine of causes in some philosophical schools in antiquity. Today the medical meaning of the term prevails.

literature

• David M. Armstrong: A World of States of Affairs . Cambridge University Press, 1997, chap. 14th
• Mario Bunge : Causality, History and Problems . Mohr, Tübingen 1987, ISBN 3-16-944806-4
• Phil Dowe: Physical Causation . Cambridge University Press, 2000
• Dieter Hattrup : Einstein against the god who rolls the dice. At the limits of knowledge in natural science and theology Herder, Freiburg im Breisgau / Basel / Vienna 2011, ISBN 978-3-451-29785-4 .
• Geert Keil: acting and causing . Frankfurt: Klostermann, 2000
• Klowski, Joachim: The historical origin of the causal principle , in: Archive for the history of philosophy 48 (1966), pp. 225–267.
• David Lewis: "Causality" (1978), in: G. Posch (Ed.): Causality, new texts. Stuttgart: Reclam, 1981, pp. 102-126
• John L. Mackie : The Cement of the Universe - A Study of Causation . Oxford: Clarendon Press, 1980
• Uwe Meixner: Theory of causality. A guide to the concept of causation in two parts , Mentis Verlag, 2001, ISBN 3-89785-185-7
• Judea Pearl : Causality , Cambridge University Press, ISBN 0-521-77362-8
• Wolfgang Stegmüller : Problems and results of the philosophy of science and analytical philosophy. Vol. 1 Explanation, justification, causality , Springer Verlag, ISBN 3-540-11804-7
• Wolfgang Stegmüller: The Problem of Causality , 1983
• Patrick Suppes : A Probabilistic Theory of Causality . North-Holland Publishing Company, Amsterdam 1970
• Erich Steitz: causality and human freedom . Oldib, Essen 2009, ISBN 978-3-939556-08-4 .

Videos

• What is causality? from the alpha-Centauri television series (approx. 14 minutes). Aired March 14, 2014.

See also

• Coincidence
• Cause and effect modeling

Web links

Wikiquote: Cause  - Quotes

philosophy

• Backwards Causation. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Probabilistic Causation. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Causation and Manipulability. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Counterfactual Theories of Causation. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Causal Processes. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• The Metaphysics of Causation. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• The Causal Mechanical Model. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Francis Longworth: Bibliography on causation , AHRC, Birmingham 2011.

physics

• Franz Josef Burghardt : The law of causation in physics , in: Physik und Didaktik 4 (1983), pp. 285-297.

History of ideas

• Julius Weinberg:  Causation in the Dictionary of the History of Ideas
• Patrick Gardiner:  Causation in History in the Dictionary of the History of Ideas
• Aristotle on Causality. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Michael E. Marmura:  Causation in islamic thought in the Dictionary of the History of Ideas
• Medieval Theories of Causation. In: Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and Parameter 2 and not Parameter 3
• Willis Doney:  Causation in the seventeenth century in the Dictionary of the History of Ideas
• Enrico de Angelis:  Causation in the seventeenth century: final causes in the Dictionary of the History of Ideas
• Leibniz on Causation. Entry in Edward N. Zalta (Ed.): Stanford Encyclopedia of Philosophy .Template: SEP / Maintenance / Parameter 1 and neither parameter 2 nor parameter 3
• Causality, Causa (with Aristotle and in the Middle Ages) . Werner Stangl's worksheets, Linz 1997.

Cognitive science (mental causation)

Cognitive linguistics

• Force Dynamics in Language and Cognition , chapter on force dynamics from Leonard Talmy, Toward a Cognitive Semantics , 2000 ( PDF ). (625 kB)

Scientific conferences and congresses on the topic of causality

• Rostock Retreat on Causality , an interdisciplinary retreat of the MPIDR : 2. – 4. July 2018, Rostock (D).

Individual evidence

1. ^ Wilhelm H. Westphal: Physics - A textbook . 25./26. Edition. Springer, 1970, p. 4th f . 
2. ↑ Max Born: Physics in the course of my time . Springer, 2013, ISBN 978-3-322-88794-8 ( limited preview in Google book search). 
3. ↑ Lexicon of Physics. Causality. Spektrum Akademischer Verlag, Heidelberg, 1998, accessed on May 1, 2016 . 
4. ↑ Ognyan Oreshkov, Fabio Costa, Časlav Brukner: Quantum correlations with no causal order . In: Nature Communications . tape 3 , 2012, p. 1092 , doi : 10.1038 / ncomms2076 . 
5. ↑ Werner Heisenberg : The part and the whole. Conversations in the area of ​​atomic physics. 9th edition, Piper, Munich 2012 (first edition 1969), ISBN 978-3-492-22297-6 , page 115.
6. ↑ Paul Davies : The Immortality of Time. Modern physics between rationality and God. Scherz, Bern a. a. 1995, page 207.
7. ↑ Deterministic Chaos. Strong and weak causality. LEIFI Physik, Joachim Herz Stiftung, Hamburg, accessed on May 1, 2016 . 
8. ↑ Cause / Effect , in: Historical Dictionary of Philosophy (Hist. Wb. Phil. 11), Vol. 11: UV, Basel 2001, Sp. 378–411, here: 411.
9. ↑ Plato: Phaedo 96e-101c.
10. ↑ Hist. Wb. Philos. 11, col. 379.
11. ↑ See Klowski 1966.
12. ↑ Hist. Wb. Philos. 11, col. 380 f.
13. ↑ David Hume: An Inquiry into the Human Mind . Translated by Raoul Richter, ed. by Jens Kulenkampff. 12th edition. Meiner, Hamburg 1993, p. 92f. Emphasis in the original.
14. ↑ David Hume: An Inquiry into the Human Mind . Translated by Raoul Richter, ed. by Jens Kulenkampff. 12th edition. Meiner, Hamburg 1993, p. 95. Italics in the original.
15. ↑ Andreas Bartels, Manfred Stöckler (Ed.): Wissenschaftstheorie , mentis Verlag, Paderborn 2009, Chapter 4: Causality, p. 89 ff.
16. ↑ KrV B 478, Academy edition: The antinomy of pure reason: Note on the third antinomy
17. ↑ CPR B 248-248 Academy Edition
18. ^ Quotes from: Michel Serres and Nayla Farouki (eds.), Thesaurus of the exact sciences, ZWEITAUSENDEINS, ISBN 3-86150-620-3
19. ↑ James E. Mazur: Learning and Behavior . Pearson Verlag, 6th edition. 2006, ISBN 978-3-8273-7218-5
20. ^ Cook, Thomas D., and Donald T. Campbell. Quasi-Experimentation: Design & Analysis Issues for Field Settings . Houghton Mifflin Company, Boston 1979.
21. ^ Fritz Heider : Social perception and phenomenal causality. In: Martin Irle (ed.), Together with Mario von Cranach and Hermann Vetter: Texts from experimental social psychology. Luchterhand: 1969. p. 26.
22. ↑ See also Dietrich von Engelhardt : Causality and conditionality in modern medicine. In: Heinrich Schipperges (Ed.): Pathogenesis. Basic features and perspectives of a theoretical pathology. Berlin / Heidelberg / New York / Tokyo 1985, pp. 32-58.