{"title":"具有观测协变量的双随机跳跃马尔可夫过程的条件相型分布","authors":"B. Surya","doi":"10.2139/ssrn.2901525","DOIUrl":null,"url":null,"abstract":"Empirical evidences on corporate bond found e.g. in Frydman (2005) and Frydman and Schuermann (2008) suggest the facts that the attribution of constant intensity in the credit rating dynamics, represented by finite-state jump Markov processes, is not borne out by actual data. On the other hand, it is known facts that continuous-time finite-state jump Markov processes can be represented by means of Poisson process and embedded discrete-time Markov chains, see, e.g., Ch. 7 of Pardoux (2008), Sec. 5.10 of Resnick (2002) and and Jakubowski and Nieweglowski (2010, 2008). Motivated by the above facts, we consider representation of jump Markov processes in terms of doubly stochastic Poisson process (see e.g. Cox (1955), Kingman (1964), Serfozo (1972), and Bremaud (1981)) whose intensity is driven by observed explanatory covariates. However, we impose weaker conditions than that of specified in Kingman (1964) and Jakubowski and Nieweglowski (2010, 2008) in the construction of such jump Markov process in which the conditional rate of jump arrival in the conditional Poisson process follows the landmarking approach. This approach has been recently introduced in event history analysis by van Houwelingen (2007) and van Houwelingen and Putter (2012). By this approach, we do not require the whole trajectory (dynamics) of the observed covariates. Analogous to Cox (1955) and Jakubowski and Nieweglowski (2010), we call such representation as doubly stochastic jump Markov processes. We derive lifetime distributions until its absorption of doubly stochastic finite state absorbing jump Markov process, and propose generalization of the phase-type distribution introduced in Neuts (1981, 1975). Also, we derive conditional forward intensity of future occurrences of the jump Markov process. The new distribution and intensity are given in closed form and have ability to capture explanatory covariates and heterogeneity. The results can be seen as an alternative structural approach to the reduced-form model of credit default discussed in Duffie et al. (2009, 2007), and Duan et al. (2012). Some numerical examples are discussed to motivate the main results.","PeriodicalId":23435,"journal":{"name":"UNSW Business School Research Paper Series","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2016-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Conditional Phase-Type Distribution Under Doubly Stochastic Jump Markov Processes with Observed Covariates\",\"authors\":\"B. 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However, we impose weaker conditions than that of specified in Kingman (1964) and Jakubowski and Nieweglowski (2010, 2008) in the construction of such jump Markov process in which the conditional rate of jump arrival in the conditional Poisson process follows the landmarking approach. This approach has been recently introduced in event history analysis by van Houwelingen (2007) and van Houwelingen and Putter (2012). By this approach, we do not require the whole trajectory (dynamics) of the observed covariates. Analogous to Cox (1955) and Jakubowski and Nieweglowski (2010), we call such representation as doubly stochastic jump Markov processes. We derive lifetime distributions until its absorption of doubly stochastic finite state absorbing jump Markov process, and propose generalization of the phase-type distribution introduced in Neuts (1981, 1975). Also, we derive conditional forward intensity of future occurrences of the jump Markov process. The new distribution and intensity are given in closed form and have ability to capture explanatory covariates and heterogeneity. The results can be seen as an alternative structural approach to the reduced-form model of credit default discussed in Duffie et al. (2009, 2007), and Duan et al. (2012). 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引用次数: 0
摘要
在Frydman(2005)和Frydman and Schuermann(2008)中发现的关于公司债券的经验证据表明,信用评级动态中以有限状态跳跃马尔可夫过程为代表的恒定强度的归因并没有得到实际数据的证实。另一方面,已知的事实是,连续时间有限状态跳跃马尔可夫过程可以用泊松过程和嵌入的离散时间马尔可夫链来表示,参见Pardoux(2008)的第7章,Resnick(2002)的第5.10节以及Jakubowski和Nieweglowski(2010, 2008)。基于上述事实,我们考虑用双随机泊松过程来表示跳跃马尔可夫过程(参见Cox(1955)、Kingman(1964)、Serfozo(1972)和Bremaud(1981)),其强度由观察到的解释协变量驱动。然而,在构造这种跳跃马尔可夫过程时,我们施加了比Kingman(1964)和Jakubowski和Nieweglowski(2010、2008)中规定的更弱的条件,其中条件泊松过程中的条件跳跃到达率遵循地标方法。这种方法最近被van Houwelingen(2007)和van Houwelingen and Putter(2012)引入到事件历史分析中。通过这种方法,我们不需要观察到的协变量的整个轨迹(动力学)。与Cox(1955)和Jakubowski和Nieweglowski(2010)类似,我们将这种表示称为双重随机跳跃马尔可夫过程。推导了其吸收双随机有限态跳跃马尔可夫过程之前的寿命分布,并对Neuts(1981,1975)中引入的相型分布进行了推广。此外,我们还推导了跳跃马尔可夫过程未来发生的条件前向强度。新的分布和强度以封闭形式给出,并且能够捕获解释协变量和异质性。研究结果可以被视为Duffie等人(2009、2007)和Duan等人(2012)讨论的信用违约简化模型的另一种结构性方法。文中还讨论了一些数值算例来激励主要结果。
Conditional Phase-Type Distribution Under Doubly Stochastic Jump Markov Processes with Observed Covariates
Empirical evidences on corporate bond found e.g. in Frydman (2005) and Frydman and Schuermann (2008) suggest the facts that the attribution of constant intensity in the credit rating dynamics, represented by finite-state jump Markov processes, is not borne out by actual data. On the other hand, it is known facts that continuous-time finite-state jump Markov processes can be represented by means of Poisson process and embedded discrete-time Markov chains, see, e.g., Ch. 7 of Pardoux (2008), Sec. 5.10 of Resnick (2002) and and Jakubowski and Nieweglowski (2010, 2008). Motivated by the above facts, we consider representation of jump Markov processes in terms of doubly stochastic Poisson process (see e.g. Cox (1955), Kingman (1964), Serfozo (1972), and Bremaud (1981)) whose intensity is driven by observed explanatory covariates. However, we impose weaker conditions than that of specified in Kingman (1964) and Jakubowski and Nieweglowski (2010, 2008) in the construction of such jump Markov process in which the conditional rate of jump arrival in the conditional Poisson process follows the landmarking approach. This approach has been recently introduced in event history analysis by van Houwelingen (2007) and van Houwelingen and Putter (2012). By this approach, we do not require the whole trajectory (dynamics) of the observed covariates. Analogous to Cox (1955) and Jakubowski and Nieweglowski (2010), we call such representation as doubly stochastic jump Markov processes. We derive lifetime distributions until its absorption of doubly stochastic finite state absorbing jump Markov process, and propose generalization of the phase-type distribution introduced in Neuts (1981, 1975). Also, we derive conditional forward intensity of future occurrences of the jump Markov process. The new distribution and intensity are given in closed form and have ability to capture explanatory covariates and heterogeneity. The results can be seen as an alternative structural approach to the reduced-form model of credit default discussed in Duffie et al. (2009, 2007), and Duan et al. (2012). Some numerical examples are discussed to motivate the main results.
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