Let the Brownian motion (b(t)) start at X0 (constant) B(0)=X0, => B(t) ~ N(X0,t) why?

Let s follow geometric Brownian motion with expected return µ and volatility σ. Show the process...

Let s follow geometric Brownian motion with expected return µ and volatility σ. Show the process followed by G(s, t) = s(a + bt), where a and b are constants, also follows geometric Brownian motion. Identify the drift and volatility terms. Please show all work

30. Efficient markets follow… a. Brownian motion b. Martingale (Brownian motion around a positive trendline) c....

30. Efficient markets follow… a. Brownian motion b. Martingale (Brownian motion around a positive trendline) c. All of the above

What is the power spectral density (PSD) of the difference D(t) of two Brownian Motion Process?...

What is the power spectral density (PSD) of the difference D(t) of two Brownian Motion Process? D(t) = B(t) − B(t−4) where t ≥ 4

Master Theorem: Let T(n) = aT(n/b) + f(n) for some constants a ≥ 1, b >...

Master Theorem: Let T(n) = aT(n/b) + f(n) for some constants a ≥ 1, b > 1. (1). If f(n) = O(n logb a− ) for some constant > 0, then T(n) = Θ(n logb a ). (2). If f(n) = Θ(n logb a ), then T(n) = Θ(n logb a log n). (3). If f(n) = Ω(n logb a+ ) for some constant > 0, and af(n/b) ≤ cf(n) for some constant c < 1, for all large n,...

Let {N(t), t ≥ 0} be a P P(λ). Compute P £ N(t) = k|N(t +...

Let {N(t), t ≥ 0} be a P P(λ). Compute P £ N(t) = k|N(t + s) = k + m ¤ for t ≥ 0, s ≥ 0, k ≥ 0, m ≥ 0

Let f(x)= a -bx^c + dx^e where a, b,c,d,e >0 and c<e. Suppose that f(x0)= 0...

Let f(x)= a -bx^c + dx^e where a, b,c,d,e >0 and c<e. Suppose that f(x0)= 0 and f '(x0)=0 for some x0>0. Prove that f(x) greater than or equal to 0 for x greater than or equal to 0

A ball moves along a 1D coordinate system with the following motion parameters at time t...

A ball moves along a 1D coordinate system with the following motion parameters at time t = 0 s: x0 = 7.7 m and v0 = 0 m/s. The ball has a constant acceleration of 1.2 m/s2 during the entire motion which occurs over a time of 3 s. Assume that an error in position of 9 % is acceptable in this application over the entire motion. How many rows N will be needed in the table to model the...

Let (pij ) be a stochastic matrix and {Xn|n ≥ 0} be an S-valued stochastic process...

Let (pij ) be a stochastic matrix and {Xn|n ≥ 0} be an S-valued stochastic process with finite dimensional distributions given by P(X0 = i0, X1 = i1, · · · , Xn = in) = P(X0 = i0)pi0i1 · · · pin−1in , n ≥ 0, i0, · · · , in ∈ S. Then {Xn|n ≥ 0} is a Markov chain with transition probability matrix (pij ). Let {Xn|n ≥ 0} be an S-valued Markov chain. Then the...

Consider the motion of a object able to move along a line under constant acceleration a....

Consider the motion of a object able to move along a line under constant acceleration a. At time t = 0, its initial position and velocity are x0 and v0 respectively. Show that at a later time t, v = v0 + at, x = x0 + v0t + 12at2. Eliminate the time between these two relations to show that a(x − x0) = 12(v2 − v20). Use this to find the minimum stopping distance for a car travelling at...

2. Let f(x) = sin(2x) and x0 = 0. (A) Calculate the Taylor approximation T3(x) (B)....

2. Let f(x) = sin(2x) and x0 = 0. (A) Calculate the Taylor approximation T3(x) (B). Use the Taylor theorem to show that |sin(2x) − T3(x)| ≤ (2/3)(x − x0)^(4). (C). Write a Matlab program to compute the errors for x = 1/2^(k) for k = 1, 2, 3, 4, 5, 6, and verify that |sin(2x) − T3(x)| = O(|x − x0|^(4)).