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Numerical Methods in Computational Finance. Daniel J. Duffy

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Numerical Methods in Computational Finance - Daniel J. Duffy

System (3.14) is sometimes called the Lotka–Volterra equations, which are an example of a more general Kolmogorov model to model the dynamics of ecological systems with predator-prey interactions, competition, disease and mutualism (Lotka (1956)).

3.3.4 Logistic Function

A logistic function (or logistic curve) is an S-shaped sigmoid curve defined by the equation:

(3.15) f left-parenthesis x right-parenthesis equals StartFraction upper L Over 1 plus e Superscript minus k left-parenthesis x minus x 0 right-parenthesis Baseline EndFraction comma

where

-value of sigmoid's midpoint

curve's maximum value

steepness of the curve.

A special case is when k equals 1 comma x 0 equals 0 comma upper L equals 1 , resulting in the standard logistic function defined by the equation:

f left-parenthesis x right-parenthesis equals StartFraction 1 Over 1 plus e Superscript negative x Baseline EndFraction period

We can verify from this equation that the logistic function satisfies the non-linear initial value problem:

(3.16) StartLayout 1st Row 1st Column StartFraction italic d f Over italic d x EndFraction equals f left-parenthesis 1 minus f right-parenthesis comma 2nd Column f left-parenthesis 0 right-parenthesis equals one half period EndLayout

The logistic function models processes in a range of fields such as artificial neural networks (learning algorithms, where it is called an activation function), economics, probability and statistics, to name a few.

3.4 EXISTENCE THEOREMS FOR STOCHASTIC DIFFERENTIAL EQUATIONS (SDEs)

A random process is a family of random variables defined on some probability space and indexed by the parameter t where t belongs to some index set. A random process is a function of two variables:

StartSet xi left-parenthesis t comma x right-parenthesis colon t element-of upper T comma x element-of upper S EndSet

where T is the index set and S is the sample space. For a fixed value of t, the random process becomes a random variable, while for a fixed sample point x in S the random process is a real-valued function of t called a sample function or a realisation of the process. It is also sometimes called a path.

The index set T is called the parameter set, and the values assumed by xi left-parenthesis t comma omega right-parenthesis are called the states; finally, the set of all possible values is called the state space of the random process.

The index set T can be discrete or continuous; if T is discrete, then the process is called a discrete-parameter or discrete-time process (also known as a random sequence). If T is continuous, then we say that the random process is called continuous-parameter or continuous-time. We can also consider the situation where the state is discrete or continuous. We then say that the random process is called discrete-state (chain) or continuous-state, respectively.

3.4.1 Stochastic Differential Equations (SDEs)

We give a short introduction to stochastic differential equations (SDEs) as they are closely related to ODEs. We discuss SDEs in more detail in Chapter 13.

We introduce the scalar random processes described by SDEs of the form:

(3.17) d xi left-parenthesis t right-parenthesis equals mu left-parenthesis t comma xi left-parenthesis t right-parenthesis right-parenthesis italic d t plus sigma left-parenthesis t comma xi left-parenthesis t right-parenthesis right-parenthesis italic d upper W left-parenthesis t right-parenthesis

where:

random process

transition (drift) coefficient

diffusion coefficient

Brownian process

given initial condition

defined in the interval [0, T]. We assume for the moment that the process takes values on the real line. We know that this SDE can be written in the equivalent integral form:

(3.18)

This is a non-linear equation, because the unknown random process appears on both sides of the equation and it cannot be expressed in a closed form. We know that the second integral:

integral Subscript 0 Superscript t Baseline sigma left-parenthesis s comma xi left-parenthesis s right-parenthesis right-parenthesis italic d upper W left-parenthesis s right-parenthesis

is a continuous process (with probability 1) provided sigma left-parenthesis s comma xi left-parenthesis s right-parenthesis right-parenthesis is a bounded process. In particular, we restrict the scope to those functions for which:

sup Underscript StartAbsoluteValue x EndAbsoluteValue less-than-or-equal-to upper C Endscripts left-parenthesis StartAbsoluteValue mu left-parenthesis s comma x right-parenthesis EndAbsoluteValue plus StartAbsoluteValue sigma left-parenthesis s comma x right-parenthesis EndAbsoluteValue right-parenthesis less-than infinity comma t element-of left-parenthesis 0 comma upper T right-bracket and for every upper C greater-than 0 period

Using this fact, we shall see that the solution of Equation (3.17) is bounded and continuous with probability 1.

We now discuss existence and uniqueness theorems. First, we define some conditions on the coefficients in Equation

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