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SDES

Stochastic differential equations (SDEs) describe the evolution of systems influenced by random effects. They extend ordinary differential equations by including terms that model noise, typically represented by Brownian motion. An SDE in n dimensions often has the form dX_t = a(X_t,t) dt + B(X_t,t) dW_t, where X_t is the state, a is the drift vector, B is the diffusion matrix, and W_t is a vector of independent Wiener processes. Solutions are stochastic processes whose paths depend on the realized noise.

Two main calculi are used to manipulate SDEs: Itô calculus and Stratonovich calculus. Itô calculus treats the

Mathematical analysis of SDEs addresses questions of existence and uniqueness of solutions, regularity, and long-term behavior.

Numerical methods are used to simulate sample paths. The Euler–Maruyama method is the simplest explicit scheme;

Applications span finance, physics, biology, and engineering. In finance, asset prices are modeled by SDEs leading

stochastic
integral
in
a
non-anticipative
way
and
leads
to
Itô's
lemma,
a
stochastic
chain
rule
essential
for
transforming
variables.
Stratonovich
calculus
aligns
with
ordinary
chain
rule
intuition
and
is
often
preferred
in
certain
physical
models.
Sufficient
conditions
typically
involve
Lipschitz
continuity
and
linear
growth
bounds
on
the
drift
and
diffusion
coefficients.
higher-order
schemes
such
as
Milstein
improve
accuracy.
In
practice,
discretization
errors
and
interpretation
of
the
noise
term
matter
for
simulations.
to
models
like
Black–Scholes;
in
physics,
Langevin
equations
describe
particles
under
random
forces;
in
biology
and
engineering,
SDEs
model
population
fluctuations
or
noisy
control
systems.