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

Gauge Integral Structures for Stochastic Calculus and Quantum Electrodynamics

Observe that the number z left-parenthesis s right-parenthesis of shares held at any time depends on whether the share price x left-parenthesis s right-parenthesis has moved up or down. So , equals z left-parenthesis x left-parenthesis s right-parenthesis right-parenthesis , is a deterministic function of ; and the value of z left-parenthesis s right-parenthesis varies randomly because varies randomly.

The same applies to the values of w left-parenthesis s right-parenthesis , including the terminal value w left-parenthesis 4 right-parenthesis , or w left-parenthesis t right-parenthesis with t equals 4 . Table 2.5 gives the respective process sample paths for processes, upper X comma upper Z comma upper W where the underlying share price process upper X follows sequence DUUU (sample number 2 in Table 2.4).

Regarding notation, the symbols upper X comma upper Z comma upper W , upper X left-parenthesis s right-parenthesis comma upper Z left-parenthesis s right-parenthesis comma upper W left-parenthesis s right-parenthesis (and so on) are used here, in contrast to symbols script upper X comma script upper Z etc. which were used in discussion of stochastic calculus in Chapter 1 . In the latter, the emphasis was on the classical rigorous theory in which random variables are measurable functions, and this is signalled by using instead of upper X , etc.

Where upper X (rather than script upper X etc.) is used, the purpose is to indicate the “naive” or “natural” outlook which sees random variability, not in terms of abstract mathematical measurable sets and functions, but in terms of actual occurrences such as tossing a coin, or such as the unpredictable rise and fall of prices.

A mathematically rigorous approach to random variation can be squarely based on the latter view, and in due course this will provide mathematical justification for notation upper X comma upper Z comma upper W etc.

Table 2.5 describes two out of a possible total of sixteen outcomes, or sample paths, for each of the processes involved. But the tables do not examine the probabilities of the various outcomes. So Table 2.4, for instance, does not really shed much light on how the investment policy of the portfolio holder (shareholder) is capable of performing. The alternative outcomes of the policy are displayed in Table 2.4, but on its own the list of outcomes does not say whether a gain of wealth is more likely than an overall loss.

What if, for instance, we wish to determine the expected overall gain in the value of the shareholding at the end of four days? With t equals 4 , what is the value⁴ of normal upper E left-bracket upper W left-parenthesis 4 right-parenthesis right-bracket ?

This can be answered directly as follows.

Suppose the different possible amounts of total or net shareholding gain are known. Two of these, and , are calculated above. There are 16 possible sample paths for the underlying process corresponding to the 16 permutations of U, D. So, allowing for duplication of values, there are at most 14 other values for total shareholding gains.

The probability of each of the 16 values of is the same as the probability of the corresponding underlying sample path (or ). It is assumed that the probability of a U or D transition is 0.5 in each case. If it is further assumed that the transitions are independent, then the probability of each of the 16 sample paths is , or one sixteenth. This is then the probability of each of 16 outcomes for total shareholding gain, including duplicated values.

The 16 values for w left-parenthesis 4 right-parenthesis can be easily calculated, as in Table 2.5 above. In fact, the 16 outcomes for net wealth (shareholding value) gain are

negative 5 comma negative 4 comma negative 4 comma negative 3 comma negative 3 comma negative 2 comma negative 2 comma negative 1 comma negative 1 comma 0 comma 1 comma 2 comma 3 comma 4 comma 5 comma 10 period

Since each of the 2 Superscript 4 Baseline equals 16 transition sequences

left-parenthesis upper U comma upper U comma upper U comma upper U right-parenthesis comma ellipsis comma left-parenthesis upper U comma upper D comma upper D comma upper U right-parenthesis comma ellipsis comma left-parenthesis upper D comma upper D comma upper D comma upper D right-parenthesis

has equal probability one half times one half times one half times one half equals one sixteenth , each of the 16 values (including duplicates) for w left-parenthesis 4 right-parenthesis has probability , or one sixteenth (due to the assumption of independence). Therefore, when all the details are fully calculated out,

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