"레비 확률 과정"의 두 판 사이의 차이

노트

위키데이터

• ID : Q1557613

말뭉치

1. Informally speaking, a Lévy process is a random trajectory, generalizing the concept of Brownian motion, which may contain jump discontinuities.^[1]
2. The terms of this triplet suggest that a Lévy process can be seen as having three independent components: a linear drift, a Brownian motion, and a Lévy jump process, as described below.^[2]
3. Khintchine theorem suggests that every Lévy process is the sum of Brownian motion with drift and another independent random variable.^[2]
4. t≥0 be a free Lévy process (in law) affiliated with aW*-probability space (𝒜, τ) and with marginal distributions (μ t ).^[3]
5. t≥0 is termed the background driving Lévy process or the BDLP corresponding to Y; this is due to its role for processes of Ornstein–Uhlenbeck type (see ref. 16).^[3]
6. Now choose a free Lévy process (Z t ) affiliated with some W*-probability space (𝒜′, τ′) and corresponding to (X t ) as in Proposition 1.2.^[3]
7. In order to describe precisely the sum of jumps of a Lévy process, one needs to introduce the concept of Poisson random measures.^[3]
8. The distributions that can appear as the distribution of the instantaneous value of a homogeneous Lévy process are exactly those that have the property called infinite divisibility.^[4]
9. The fact that a Lévy process τ exists such that τ(1) is generalized inverse Gaussian distributed follows because these distributions are infinitely divisible, as mentioned in Section 1.^[4]
10. This model is the generalized hyperbolic Lévy process with a gamma mixing distribution.^[4]
11. A theory of the term structure of interest rates based on the hyperbolic Lévy process was developed in Eberlein and Raible (1999).^[4]
12. In this paper we compute equivalent martingale measures when the asset price returns are modelled by a Lévy process.^[5]
13. Moreover, the original process is still a Lévy process under this new probability and is called the Esscher transform of the original process.^[5]
14. and we consider a Lévy process with the following triplet (0,0, P ).^[5]
15. In this paper we have used a Lévy process to model asset price returns, which allow us to capture more stylized facts from real data.^[5]
16. This Demonstration shows the path of a symmetric stable Lévy process.^[6]
17. For , the stable Lévy process coincides with ordinary Brownian motion.^[6]
18. A strictly stable Lévy process can be viewed as a generalization of Brownian motion, and has the property for all , , has the same distribution as , for some index of stability , where .^[6]
19. This method allows the residual to submit to a Lévy process.^[7]
20. In this part, a dynamic asset distribution evolution process based on Lévy process and asymmetrical heteroscedastic process is built.^[7]
21. We assume that the residual in (1) submits to infinite-jump Lévy process and it is recorded as .^[7]
22. Infinite-jump Lévy process usually has three characteristic items, , , and , representing linear drift, Brownian motion diffusion, and jump, respectively.^[7]
23. More generally, it is possible to define the notion of a Lévy process with respect to a given filtered probability space .^[8]
24. In particular, if X is a Lévy process according to definition 1 then it is also a Lévy process with respect to its natural filtration .^[8]
25. The most common example of a Lévy process is Brownian motion, where is normally distributed with zero mean and variance independently of .^[8]
26. This is called a Cauchy process, which is a purely discontinuous Lévy process.^[8]
27. A typical model is obtained by considering finite dimensional linear stochastic SISO systems driven by a Levy process.^[9]
28. In this paper we consider a discrete-time version of this model driven by the increments of a Levy process, such a system will be called Levy system.^[9]

소스

메타데이터

위키데이터

• ID : Q1557613

Spacy 패턴 목록

• [{'LOWER': 'lévy'}, {'LEMMA': 'process'}]
• [{'LOWER': 'levy'}, {'LEMMA': 'process'}]