Quantum Probability: Sets & Complex Numbers

In summary, probability can be described using axiomatic set theory and the cardinality of sets. Quantum probability is related to the magnitude of the wave function for a particular state. Complex numbers can represent the size of a set, while real numbers cannot. The axioms for probability are similar to those for measure theory, with the addition of the probability of the entire space being one.
  • #1
closet mathemetician
44
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Classically, probability can be described using axiomatic set theory, where probabilities are related to the cardinality (size) of the sets involved.

For a quantum probability, the probability of a particular state is the squared magnitude of the wave function (eigenfunction) for that state's eigenvalue.

Relating this back to sets, what sort of a set has a complex number representing its cardinality? Or, more specifically, how can a complex number represent the "size" of a set?
 
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  • #2
closet mathemetician said:
...how can a complex number represent the "size" of a set?

And a couple of real numbers, can they?
 
  • #3
Classically, probability can be described using axiomatic set theory, where probabilities are related to the cardinality (size) of the sets involved.
Probability axiomatics uses set theory (sigma algebras and all that), but cardinality has nothing to do with it. The axioms for probability resemble those for measure theory, plus the addition that the probability (measure) of the entire space is one.
 

1. What is quantum probability and how does it differ from classical probability?

Quantum probability is a mathematical framework used to describe the probabilistic behavior of quantum systems. It differs from classical probability in that it allows for the description of non-deterministic events and the use of complex numbers to represent probabilities.

2. What are sets and how are they used in quantum probability?

Sets are collections of objects or elements that are used to describe the possible outcomes of a quantum system. In quantum probability, sets are used to represent the possible states of a quantum system, and their interactions are described using operations such as union, intersection, and complement.

3. What are complex numbers and why are they important in quantum probability?

Complex numbers are numbers that have both a real and imaginary component. They are important in quantum probability because they allow for the representation of non-deterministic events and the superposition of states in quantum systems. Complex numbers also enable the use of mathematical tools such as linear algebra to analyze and describe quantum phenomena.

4. How is quantum probability used in practical applications?

Quantum probability has a wide range of practical applications, including in quantum computing, cryptography, and quantum information theory. It is also used in fields such as chemistry, biology, and materials science to model and understand the behavior of quantum systems.

5. Are there any limitations to using quantum probability?

One limitation of quantum probability is that it is a mathematical framework and does not provide a complete understanding of the underlying physical processes in quantum systems. It also has its own set of rules and principles that may not always align with our classical intuition. Additionally, the use of complex numbers can make calculations and interpretations more complex. However, these limitations do not diminish the usefulness and power of quantum probability in describing and predicting the behavior of quantum systems.

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