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Chapter 3: Problem 4

Let \(\left\\{W_{t}\right\\}_{t \geq 0}\) be standard Brownian motion under the measure \(\mathbb{P}\). Which of the following are P-Brownian motions? (a) \(\left\\{-W_{t}\right\\}_{t \geq 0}\) (b) \(\left\\{c W_{t / c^{2}}\right\\}_{t \geq 0}\), where \(c\) is a constant, (c) \(\left\\{\sqrt{t} W_{1}\right\\}_{t \geq 0}\) (d) \(\left\\{W_{2 x}-W_{t}\right\\}_{t \geq 0}\) Justify your answers.

Short Answer

Expert verified
(a) and (b) are P-Brownian motions; (c) and (d) are not.

Step by step solution

01

Check Part a

To determine if \( \{-W_t\}_{t \geq 0} \) is a \( \mathbb{P} \)-Brownian motion, we need to verify if it satisfies the properties of standard Brownian motion: 1. \(-W_0 = 0\).2. For \(0 \leq s < t\), \(-W_t - (-W_s) = -(W_t - W_s) \sim \mathcal{N}(0, t-s)\).3. The increments are independent.4. The paths are continuous.These properties hold due to symmetry of the normal distribution and the properties of standard Brownian motion. Thus, \( \{-W_t\}_{t \geq 0} \) is a \( \mathbb{P} \)-Brownian motion.
02

Check Part b

Consider \( \{c W_{t/c^2}\}_{t \geq 0} \). For it to be a \( \mathbb{P} \)-Brownian motion:1. \(c W_0 = 0\).2. For \(0 \leq s < t\), \(c(W_{t/c^2} - W_{s/c^2}) \sim \mathcal{N}(0, t-s)\).3. Increments must be independent due to Brownian properties.4. Paths are continuous as \( W_t \) has continuous paths.Since \(c^2\) and \(1/c^2\) scale variance to \(t-s\), \(\{c W_{t/c^2}\}_{t \geq 0} \) is a \( \mathbb{P} \)-Brownian motion.
03

Check Part c

For \( \{\sqrt{t} W_1\}_{t \geq 0} \) to be a \( \mathbb{P} \)-Brownian motion:1. \(\sqrt{0} W_1 = 0\).2. For \(0 \leq s < t\), \(\sqrt{t} W_1 - \sqrt{s} W_1\) describes neither independent nor Gaussian increments.3. \( \sqrt{t} W_1 \) is deterministic at each time point since \( W_1 \) is fixed at \(t=1\) and doesn't capture a standard Brownian path.Therefore, \( \{\sqrt{t} W_1\}_{t \geq 0} \) is not a \( \mathbb{P} \)-Brownian motion as it lacks independent and Gaussian increments.
04

Check Part d

Examine \( \{W_{2t} - W_t\}_{t \geq 0} \). It needs to satisfy:1. \( W_{2 \cdot 0} - W_0 = 0 \).2. For \(0 \leq s < t\), \((W_{2t} - W_t) - (W_{2s} - W_s) = (W_{2t} - W_{2s}) - (W_t - W_s)\). This expression does not follow a normal distribution with variance \(t-s\).3. Because of the dependence on \(W_t\), increments are not independent.Thus, \( \{W_{2t} - W_t\}_{t \geq 0} \) does not satisfy all Brownian motion properties and is not a \( \mathbb{P} \)-Brownian motion.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Probability Measure
Probability measure is a fundamental concept in probability theory. It assigns a probability, a number between 0 and 1, to every possible outcome of a random event. It's like assigning degrees of certainty to events. If an event is impossible, it gets a probability of 0. If an event is certain, it gets a probability of 1.
Probability measure is defined over a sigma-algebra, which is a collection of subsets of a sample space. This ensures that probabilities are logical and consistent.
In the context of Brownian motion,
  • The probability measure, denoted as \(\mathbb{P}\), plays a crucial part in defining the properties of the motion.
  • It ensures that mathematical representations of randomness in Brownian motion are accurate.
  • Measurement of occurrences of paths is in line with the stochastic nature of the process.
This measure guarantees that all the well-known properties of Brownian motion, such as continuous paths and independent increments, remain valid. Understanding this measure is crucial when analyzing if a stochastic process is a Brownian motion.
Standard Brownian Motion
Standard Brownian Motion  is a specific and widely used type of stochastic process. It describes the random motion of particles suspended in a fluid. This concept has deep mathematical background described by a set of properties:
  • Starts at zero: At time zero, the process begins at zero.
  • Continuous paths: The paths or sample paths are continuous without any jumps.
  • Independent increments: The increments between any two time points are independent of previous increments.
  • Normally distributed increments: For any time increment, the change follows a normal distribution with mean zero and variance equal to the time increment \((t-s)\).
These properties make it a key model for various phenomena in fields like physics, finance, and mathematics.Recognizing these characteristics allows for determining whether a given process is indeed a Brownian motion or not, as each scenario in the exercise hints towards inspecting these details.
Mathematics Education
Mathematics education often deals with complex concepts such as Brownian motion and probability theory, primarily taught in advanced courses. Effective education employs:
  • Visual aids: Graphs and simulations to illustrate continuous paths and random walks, making abstract concepts tangible.
  • Step-by-step derivations: Breaking down proof processes and calculations as seen in the exercise solution aids comprehension.
  • Real-world examples: Utilizing physical phenomena like particle movement to relate mathematical concepts to tangible experiences.
These techniques are vital for fostering a deeper understanding. They not only assist students in solving textbook exercises but also provide them with practical insight into how these concepts apply to real-world situations. Practical application in educational settings enhances students' ability to tackle similar problems independently.
Stochastic Processes
Stochastic processes are mathematical objects used to describe systems that evolve over time with inherent randomness. They are everywhere, from physics to finance.
  • Key characteristic: Their future behavior is not entirely predictable due to randomness.
  • Used to model: Various real-world phenomena like stock prices and physical particle movement.
  • Consist of: Sequences of random variables indexed by time.
Among stochastic processes, Brownian motion stands out due to its mathematical tractability and relevance to real-world scenarios. Understanding stochastic processes involves recognizing the types of behaviors they can exhibit, such as continuity in Brownian paths or independence of increments.
Mastering these ideas, as illustrated in the exercise, equips students with the skills to analyze complex random systems.

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Most popular questions from this chapter

Let \((\Omega, \mathcal{F}, \mathbb{P})\) be a probability space. Suppose that the real random variable \(T: \Omega \rightarrow\) \(\mathbb{R}\) is uniformly distributed on \([0,1]\) under the measure \(\mathbb{P}\). Define \(\left\\{X_{t}\right\\}_{t \geq 0}\) by $$ X_{t}(\omega)= \begin{cases}1, & T(\omega)=t \\ 0, & T(\omega) \neq t\end{cases} $$ Check that \(\left\\{X_{t}\right\\}_{t \geq 0}\) is a P-martingale with respect to its own filtration. [Hint: Conditional expectation is only unique to within a random variable that is almost surely zero.] Show that \(T\) is a stopping time for which the Optional Stopping Theorem fails.

Suppose that \(X\) is normally distributed with mean \(\mu\) and variance \(\sigma^{2}\). Calculate $$ \mathbb{E}\left[e^{\theta X}\right] $$ and hence evaluate \(\mathbb{E}\left[X^{4}\right]\).

Prove that if \(\left\\{W_{t}\right\\}_{t \geq 0}\) is standard Brownian motion under \(\mathbb{P}\) then, for \(x>0\) $$ \mathbb{P}\left[W_{t} \geq x\right] \equiv \int_{x}^{\infty} \frac{1}{\sqrt{2 \pi t}} e^{-y^{2} / 2 t} d y \leq \frac{\sqrt{t}}{x \sqrt{2 \pi}} e^{-x^{2} / 2 t} $$

Let \(\left\\{W_{t}\right\\}_{t \geq 0}\) denote standard Brownian motion under \(\mathbb{P}\) and define \(\left\\{M_{t}\right\\}_{r \geq 0}\) by $$ M_{t}=\max _{0 \leq s \leq t} W_{s} $$ Suppose that \(x \geq a .\) Calculate (a) \(\mathbb{P}\left[M_{t} \geq a, W_{t} \geq x\right]\), (b) \(\mathbb{P}\left[M_{t} \geq a, W_{t} \leq x\right]\).

Suppose that \(\left\\{W_{t}\right\\}_{t \geq 0}\) is standard Brownian motion. Prove that conditional on \(W_{t_{1}}=\) \(x_{1}\), the probability density function of \(W_{t_{1} / 2}\) is $$ \sqrt{\frac{2}{\pi t_{1}}} \exp \left(-\frac{1}{2}\left(\frac{\left(x-\frac{1}{2} x_{1}\right)^{2}}{t_{1} / 4}\right)\right) $$
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