Gauge Integral Structures for Stochastic Calculus and Quantum Electrodynamics. Patrick Muldowney

Gauge Integral Structures for Stochastic Calculus and Quantum Electrodynamics

the sum being taken over all 16 values (including duplicate values) of total gain w left-parenthesis 4 right-parenthesis .

When duplicate values are combined, there are 12 distinct outcomes for w left-parenthesis 4 right-parenthesis . Each of the duplicated outcomes negative 1 comma negative 2 comma negative 3 comma negative 4 has probability one eighth , while each of the other 8 distinct outcomes has probability one sixteenth .

To find the expected value of upper W left-parenthesis 4 right-parenthesis (or script upper W 4 ) in accordance with the classical, rigorous mathematical theory of probability, it should be formulated in terms of a probability space left-parenthesis normal upper Omega comma upper P comma script upper A right-parenthesis , so

(2.7) normal upper E left-parenthesis script upper W left-parenthesis 4 right-parenthesis right-parenthesis comma equals normal upper E left-parenthesis script upper W 4 right-parenthesis equals integral Underscript normal upper Omega Endscripts script upper W 4 left-parenthesis omega right-parenthesis d upper P period

There are many ways in which a sample space normal upper Omega can be constructed. One way is to let be the set of numbers consisting of the different values of w left-parenthesis 4 right-parenthesis (i.e. without duplicate values), of which there are 12, and let upper P be the appropriate atomic probability measure on these 12 values. Letting upper W 4 be the identity function on normal upper Omega , (or script upper W 4 ) is measurable (trivially), and

normal upper E left-parenthesis script upper W 4 right-parenthesis equals normal upper E left-bracket upper W left-parenthesis 4 right-parenthesis right-bracket equals 0 comma

because the integral in (2.7) reduces to the sum in (2.6.

Now suppose that, at times s equals 1 comma 2 comma 3 comma 4 , the probability of an Up transition in x left-parenthesis s right-parenthesis is two thirds , while the probability of a Down transition in is one third :

upper P left-parenthesis upper U right-parenthesis equals two thirds comma upper P left-parenthesis upper D right-parenthesis equals one third comma

and suppose, as before, that Up or Down transitions are independent of each other; so, for instance, the joint transition sequence U‐D‐D‐U (and the corresponding w left-parenthesis 4 right-parenthesis equals negative 1 ) has probability

upper P left-parenthesis upper U upper D upper D upper U right-parenthesis equals two thirds times one third times one third times two thirds equals four eighty-firsts semicolon

with similar probability calculations for each of the other 15 transition paths and their corresponding w left-parenthesis 4 right-parenthesis values (including duplicates, such as D‐U‐U‐U which also gives ).

The 16 outcomes (including replicated outcomes) for accumulated gain w left-parenthesis 4 right-parenthesis are the same as before, but because the probabilities are different, the expected net gain is now normal upper E left-parenthesis script upper W 4 right-parenthesis equals integral Underscript normal upper Omega Endscripts script upper W left-parenthesis omega right-parenthesis d upper P equals eight thirds comma or

(2.8) normal upper E left-bracket upper W left-parenthesis 4 right-parenthesis right-bracket equals sigma-summation w left-parenthesis 4 right-parenthesis upper P left-parenthesis w left-parenthesis 4 right-parenthesis right-parenthesis equals eight thirds period

Both calculations reduce to the same finite sum of terms. It is seen here that the new probability distribution, favouring Up transitions, produces an overall net gain in wealth through the policy of acquiring shares on an up‐tick, while not shedding shares on a down‐tick—the “optimistic” policy, in other words.

If the joint transition probabilities

upper P left-parenthesis upper U right-parenthesis equals upper P left-parenthesis upper D right-parenthesis equals one half comma bold or upper P left-parenthesis upper U right-parenthesis equals two thirds comma upper P left-parenthesis upper D right-parenthesis equals one third comma

are not independent, then, provided the dependencies between the various transitions and events are known, it is still possible to calculate all the relevant joint probabilities. But generally this is not so simple as the rule (of multiplying the component probabilities) that obtains when the joint occurrences are independent of each other.

A key step in the analysis is the construction of the probabilities for the values w left-parenthesis 4 right-parenthesis of the random variable upper W left-parenthesis 4 right-parenthesis (or script upper W 4 ). The framework for this is as follows. Consider any subset upper A of the sample space

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