User:Johnjbarton/sandbox/ensemble

Probability; propensity
Quantum observations are inherently statistical. For example, the electrons in a low-intensity double slit experiment arrive at random times and seemingly random places and yet eventually show an interference pattern. The theory of quantum mechanics offer only statistical results. Given that we have prepared a system in a state $$\psi$$, the theory predicts a result $$a_j$$ as a probability distribution:
 * $$P(a_j|\psi)=||^2$$.

Different approaches to probability can be applied to connect the probability distribution of theory to the observed randomness.

Popper, Ballentine, Paul Humphreys, ,  and others point to propensity as the correct interpretation of  probability in science. Propensity, a form of causality that is weaker than determinism, is the tendency of a physical system to produce a result. Thus the mathematical statement
 * $$Pr(e|G) = r $$

means the propensity for event $$e$$ to occur given the physical scenario $$G$$ is $$r$$. The physical scenario is view as weakly causal condition.

The weak causation invalidates Bayes' theorem and correlation is no longer symmetric. As noted by Paul Humphreys, many physical examples show the lack of reciprocal correlation, for example, the propensity for smokers to get lung cancer does not imply lung cancer has a propensity to cause smoking.

Propensity closely matches the application of quantum theory: single event probability can be predicted by theory but only verified by repeated samples in experiment. Popper explicitly developed propensity theory to eliminate subjectivity in quantum mechanics.