Causal reasoning
Causal reasoning is the process of identifying causality: the relationship between a cause and its effect. The study of causality extends from ancient philosophy to contemporary neuropsychology; assumptions about the nature of causality may be shown to be functions of a previous event preceding a later one. The first known protoscientific study of cause and effect occurred in Aristotle's Physics.[1] Causal inference is an example of causal reasoning.
Understanding cause and effect
Causal relationships may be understood as a transfer of force.[2] If A causes B, then A must transmit a force (or causal power) to B which results in the effect. Causal relationships suggest change over time; cause and effect are temporally related, and the cause precedes the outcome.[3]
Causality may also be inferred in the absence of a force, a less-typical definition.[4] A cause can be removal (or stopping), like removing a support from a structure and causing a collapse or a lack of precipitation causing wilted plants.
Humans can reason about many topics (for example, in social and counterfactual situations and in the experimental sciences) with the aid of causal understanding.[3] Understanding depends on the ability to comprehend cause and effect. People must be able to reason about the causes of others’ behavior (to understand their intentions and act appropriately) and understand the likely effects of their own actions. Counterfactual arguments are presented in many situations; humans are predisposed to think about “what might have been”, even when that argument has no bearing on the current situation.
Cause-and-effect relationships define categories of objects.[5] Wings are a feature of the category "birds"; this feature is causally interconnected with another feature of the category, the ability to fly.[5]
Traditionally, research in cognitive psychology has focused on causal relations when the cause and the effect are both binary values; both the cause and the effect are present or absent.[6][7] It is also possible that both the cause and the effect take continuous values. For example, turning the volume knob of a radio (as the cause) increases or decreases the sound intensity (as the effect). In these cases, the relation between the variables of the cause and the effect resembles a mathematical function in which change in the variable of the cause changes values in the variable of the effect. Human learning of such relations has been studied in the field of "Function Learning".[8][9][10]
Even so, it is well understood that physical applications of continuous mathematical models are not literally continuous in practice.[11] A knob on a radio does not take on an uncountably infinite number of possible values—it takes a finite number of possible values fully limited by the mechanical, physical, nature of the knob itself. There exists no one-to-one mapping between the continuous mathematics used for engineering applications and the physical product(s) produced by the engineering. Indeed, this is one of the core open problems within Philosophy of Mathematics.[12][13][14] While this is one of the most prominent open problems in the philosophy of mathematics, one possible answer to this open question is that reality is rasterized (possibly at the Planck Scale, see Loop Quantum Gravity) and is fundamentally discrete. So goes the theory of mathematical fictionalism, where continuous mathematics serves as a fake or fictional construct of imagery used for reasoning geometrically via drawings and intuitive ideas of shapes absent of measurement data. Indeed, some historical thinkers, such as Gauss, suspected that physical reality was in fact inherently non-euclidean and so developed non-euclidean geometries [15] which were then used by Albert Einstein in his general theory of relativity with gravity being explained as the force or property which makes reality non-euclidean.
Cause and effect may also be understood probabilistically, via inferential statistics. Consider a common example taught in introductory logic, a statement such as 'the ground is wet.' Often the specific example is presented as a conditional statement, 'If it rained, then the ground is wet' or something along this line. And often the fact that such a conditional statement is in fact true even when the antecedent (that it rained) is false generates some controversy.
This fact about the conditional, the controversial (for some) law of excluded middle, hinges on reasoning about cause and effect. You might think, for instance, that the fact that it rained is what caused the ground to be wet, if it rained and the ground is wet. But it could well be that it rained after the ground was already wet, or any other possible cause of the observed effect.
These other possible causes are called 'hidden variables.' Hidden variables always cause conditional statements to take a 'true' truth value in situations where the antecedent is false and its conclusion true. Consequently, it follows that any logical conditional with a true conclusion is always true regardless of whether or not its antecedent is true. And any logical conditional takes a false value only when its conclusion is false. This shouldn't be surprising.
In inferential statistics, there exists a mantra 'correlation does not equal causation.' Just because rain and wet grounds do have a positive correlation (they tend to happen together), without more information it would be impossible to know whether or not it was in fact the rain which caused the ground to become wet, so the positive correlation is insufficient for causation. A dump truck could well have come by and dumped out a truckload of water onto the ground, or a man could have dropped his water, or any number of other possible antecedents could be responsible for causing the conclusion that the ground is in fact wet to be true.
In this way, ascertaining cause and effect relations is quite hard and arguably impossible barring some variable uncertain degree of confidence in some specific possible cause in relation to all other uncontrolled for potentially equally or unequally probable but still possible causes (some non-100% degree of confidence, known as a confidence interval in inferential statistics). Incidentally, this problem of hidden variables forms the foundation for the scientific method—which is a solution to this problem of hidden variables. Only via the scientific method can one be absolutely sure that some true antecedent causes a conclusion to also be true. We say a cause causes an effect if and only if there exists a 100% perfect correlation (positive or negative) between the cause and the effect when and only when all other possible variables are controlled for (a 100% degree of confidence). In these cases these effects are called dependent variables, and causes are called independent variables (so named because the dependent variable(s) depend on the independent variable(s), and the independent variable(s) do not depend on any other variable).
Indeed, when possible hidden variables cannot be controlled for, such as is the case of quantum physics, causality is indeterminate (quantum indeterminacy).[16] This constitutes one of the biggest open problems in physics today, the interpretation of quantum physics and its reconciliation with the causal structure of special relativity (Einstein-Podolsky-Rosen paradox, Rietdijk–Putnam argument).
Theories of causality also play important roles in debates of both free will and determinism. The empirical observations predicted by special relativity suggest that anything that could happen, already has happened.[17] Depending on your philosophy of mathematics, since special relativity is a continuous mathematical model, the experimental confirmation of predicted effects described by the possibly fictional and conceptually-reliable-and-informative theory have implications for an ontology of time, which touches on the metaphysics of time which is intimately tied up with notions of causality and reasoning about cause and effect.[18]
And the (for now) indeterminism of quantum physics suggests the possibility of free will in a deterministic reality.[19][20] To quote Hameroff, "quantum state reductions seem to involve temporal non-locality, able to refer quantum information both forward and backward in what we perceive as time, enabling real-time conscious causal action. Quantum brain biology and Orch OR can thus rescue free will" (Orchestrated Objective Reduction).
Inferring cause and effect
Humans are predisposed to understand cause and effect, making inferences bi-directionally. Temporal cues demonstrate causality.[21] When observing an event, people assume that things preceding the event cause it, and things following the event are effects of it.[22]
Coincidence of movement and spatial relationships are another way to infer cause and effect. If objects move together (or one object seems to initiate the movement of another), causality is inferred from that relationship.[23] Animacy may also be inferred from such relationships.
Causal reasoning may be activated almost automatically.[3][24] However, inferences about cause and effect do not always demonstrate understanding of mechanisms underlying causality; causality has been described as "cognitive illusion".[25] Much understanding of cause and effect is based on associations, without an understanding of how events are related to one another.[26]
A 2013 neuropsychology study[27] demonstrates that humans conform new information to old information. This suggests an inverted causal experience: cause must be attributed to effect a posteriori to understand the causal connection between agent and act. Friedrich Nietzsche argued against Aristotelian causality (that cause precedes effect) in The Will To Power.[28]
Humans understand cause and effect. Research suggests that other animals, such as rats[29] and monkeys,[30] may or may not understand cause and effect. Animals may use information about cause and effect to improve decision-making and make inferences about past and future events.[31] A constant which guides human reasoning and learning about events is causality.[32] Causal considerations are integral to how people reason about their environment.[3] Humans use causal cues and their related effects to make decisions and predictions and to understand mechanisms leading to change.[33]
Types of causal relationships
Several types of causal models are developed as a result of observing causal relationships: common-cause relationships, common-effect relationships, causal chains and causal homeostasis.[26]
- In common-cause relationships, a single cause has several effects:
- A virus is an example of a single cause resulting in several effects (fever, headache and nausea).
- In common-effect relationships, several causes converge in one effect:
- An increase in government spending is an example of one effect with several causes (reduced unemployment, decreased currency value, and increased deficit).
- In causal chains one cause triggers an effect, which triggers another effect:
- An example is poor sleep leading to fatigue, which leads to poor coordination.
- In causal homeostasis, causal relationships form a stable cycle or reinforcing mechanism:
- Feathers, hollow bones, high metabolic rate and flight reinforce each other in birds, with adaptation to the whole rather than one instance beginning a causal relationship.[26]
Types of causal reasoning
While causal understanding can be automatic, in complex situations advanced reasoning is necessary. Types of causal reasoning[2] include:
Deduction
Deductive reasoning implies a general rule; an event is a guaranteed conclusion. An outcome may be deduced based on other arguments, which may determine a cause-and-effect relationship.
Induction
Inductive reasoning is an inference made with uncertainty; the conclusion is likely, but not guaranteed. Induction can be used to speculate about causality.
Abduction
In abductive reasoning, the premises do not guarantee a conclusion. Abduction moves from data description to a hypothesis without a necessary relationship between cause and effect.
Models
There are several models of how humans reason about causality.
Dependency
The dependency model asserts that effects are contingent upon causes;[3] cause and effect have a probable relationship.
Covariation
The covariation (regularity) model, a type of dependency model, suggests that humans understand relationships between causes and effects by their coincidence, inferring that change in a cause changes an effect.[34]
Mechanism
This model[2] suggests that cause and effect are mechanistically related. In this situation, there is a basic process underlying the cause and effect.
Development in humans
Children develop an ability to understand causality and make inferences based on cause and effect at an early age;[24] some research suggests that children as young as eight months can understand cause and effect.[37] An understanding of mechanism and causality go hand in hand; children need to understand cause and effect to understand the operation of mechanisms, which allows them to understand causal relationships.[26] Children ask "why?" at an early age to understand mechanism and, in turn, causality. A child's first "why" question often coincides with their first attempt to explain something, within the first year after acquiring language.[26] Children ask "why" to understanding mechanism and causality.[38]
The ability to understand and reason about causality at a young age allows children to develop naïve theories about many topics. Causality helps children learn about physics, language, concepts and the behavior of others.[24] There is a developmental pattern to the causal understanding children have.[38]
Infants have an understanding of causal power.[26] They know that certain causes have particular effects. Young children, from late infancy to early childhood, understand functional relations:[26] a particular property (or component of a mechanism) has a certain function. They also understand causal density: how causes can interact in a complex way.
Older children and adults continue to develop an understanding of mechanistic fragments.[26] They understand the components of a working system in isolation, although the full mechanistic details of a system do not emerge until adulthood. Jean Piaget defined preoperational, concrete operational and formal operational stages of development.
Across cultures
Causal attributions have been shown to be dissimilar among different cultures in several ways:
Causal attributions
Yan and Gaier[39] investigated causal attributions of college success and failure between two groups of students, American and Asian. The Asian group was from China, Korea, Japan and Southeast Asia. Performance was similar across the four nationalities. The students were asked to make judgments about someone else's successes and failures in schoolwork, and whether those outcomes were attributable to innate ability or to expended effort. American participants were much more likely to attribute academic achievement to ability than Asian participants were. Although Americans tended to rate success as attributable to effort, failure was not perceived as being a result of a lack of effort. Asian students did not show this pattern.
Comparisons between Western and Eastern children and adults suggest differences between the cultures in the causality attributable to particular illnesses.[40] After reading stories of illnesses and making inferences about the causes of those illnesses, both groups showed an understanding of the biological causes of most illnesses. However, all the children and the Eastern adults also attributed some illnesses (and their remedies) to magical causes.
Causal motivations
Members of individualist or collectivist cultures may make different attributions of the origins and motivations of movement on a small scale among animated objects, or what would cause movement within a group of animated objects.[41] Participants from the UK, China and Hong Kong were shown videos of animated fish on a computer screen. The videos depicted a central fish moving toward or away from a group of fish, and participants were asked to determine the relationship among the fish: internally motivated (the central fish was looking for food) or externally motivated (the central fish wanted to join the others). Another set of videos suggested that the group of fish was the predominant agent, with the individual fish being acted upon. These different videos provided an opportunity to determine whether group or individual action is the preferred motivating force among different cultures.
Self-reported results suggested that Asian participants preferred descriptions and situations where the group was the central focus and causal agent, while Westerners preferred situations in which the individual was the agent. These effects also extended to memory processes; collectivist participants had better memories of situations in which the group was primary. This suggests that members of individualistic cultures are more responsive to independent agents and members of collectivist cultures are more responsive when groups guide individual action.
Causal reasoning in non-human animals
Causal reasoning is not unique to humans; animals are often able to use causal information as cues for survival.[25] Rats are able to generalize causal cues to gain food rewards. Animals such as rats can learn the mechanisms required for a reward by reasoning about what could elicit a reward.[25]
New Caledonian crows have been studied for their ability to reason about causal events. This intelligent species uses tools in a way that even chimpanzees cannot, making complex tools to bring food within reach.[42]
Experimental work with this species suggests that they can understand hidden causes in a way that was previously believed uniquely human.[43] In the first of two experiments a crow was confined, with food in a tube inaccessible to the crow without some effort. A human entered the enclosure and went behind a curtain, waving a stick near the food tube through a hole in the curtain. When the human left the enclosure the crow confidently moved toward the food area and retrieved the reward, knowing that the human cause of the moving stick (albeit invisible) was gone. In the second experiment, no human entered or exited the enclosure. In this case the crow moved toward the food uncertainly, not knowing what caused the stick to move.
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