I consider continuous time asset pricing models with stochastic differential utility
incorporating decision makers' concern with ambiguity on true probability measure.
In order to identify and estimate key parameters in the models, I use a novel econometric
methodology developed recently by Park (2008) for the statistical inference on
continuous time conditional mean models. The methodology only imposes the condition
that the pricing error is a continuous martingale to achieve identification, and
obtain consistent and asymptotically normal estimates of the unknown parameters.
Under a representative agent setting, I empirically evaluate alternative preference
specifications including a multiple-prior recursive utility. My empirical findings are
summarized as follows: Relative risk aversion is estimated around 1.5-5.5 with ambiguity
aversion and 6-14 without ambiguity aversion. Related, the estimated ambiguity
aversion is both economically and statistically significant and including the ambiguity
aversion clearly lowers relative risk aversion. The elasticity of intertemporal substitution
(EIS) is higher than 1, around 1.3-22 with ambiguity aversion, and quite high
without ambiguity aversion. The identification of EIS appears to be fairly weak, as
observed by many previous authors, though other aspects of my empirical results
seem quite robust.
Next, I develop an approach to test for martingale in a continuous time framework.
The approach yields various test statistics that are consistent against a wide
class of nonmartingale semimartingales. A novel aspect of my approach is to use a time change defined by the inverse of the quadratic variation of a semimartingale,
which is to be tested for the martingale hypothesis. With the time change, a continuous
semimartingale reduces to Brownian motion if and only if it is a continuous
martingale. This follows immediately from the celebrated theorem by Dambis, Dubins
and Schwarz. For the test of martingale, I may therefore see if the given process
becomes Brownian motion after the time change. I use several existing tests for
multivariate normality to test whether the time changed process is indeed Brownian
motion. I provide asymptotic theories for my test statistics, on the assumption that
the sampling interval decreases, as well as the time horizon expands. The stationarity
of the underlying process is not assumed, so that my results are applicable also to
nonstationary processes. A Monte-Carlo study shows that our tests perform very well
for a wide range of realistic alternatives and have superior power than other discrete
time tests.
Identifer | oai:union.ndltd.org:tamu.edu/oai:repository.tamu.edu:1969.1/ETD-TAMU-2009-08-7167 |
Date | 14 January 2010 |
Creators | Jeong, Dae Hee |
Contributors | Park, Joon Y. |
Source Sets | Texas A and M University |
Language | en_US |
Detected Language | English |
Type | Book, Thesis, Electronic Dissertation |
Format | application/pdf |
Page generated in 0.0022 seconds