Graphical models and variational Bayesian inference for financial networks
After the 2008 financial crisis, researchers found it’s necessary to understand the financial market as a network of institutions where connections among participants play an essential role in the contagion of systemic risk. To learn financial networks, network models based on correlations are su...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2019
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/77046 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | After the 2008 financial crisis, researchers found it’s necessary to understand the financial market
as a network of institutions where connections among participants play an essential role in the
contagion of systemic risk. To learn financial networks, network models based on correlations
are superior but have limited modeling power. In this thesis, we propose a more powerful
framework of graphical models, which is applicable to monoscale, multiscale and time-varying
cases with sparse graphical representation. Existing frequentist methods for learning graphical
models need to tackle penalty parameter selection while here we provide a tuning-free
variational Bayesian inference by approximating the intractable posterior distribution by the
variational distribution. It imposes shrinkage priors on the off-diagonal elements of the precision
matrix, approximates the posterior distribution of the precision by Wishart distribution
and then employs natural gradient-based optimization. The objective of multiscale model is to
capture long-range correlations between distant sites while the time-varying graphical model
aims to obtain smoothly-evolving networks across time. Simulated data is used to compare
the performance of our models with other frequentist approaches. It shows that our models
can better recover the true graph with fewer parameters and less computational time. Then
we apply models to infer financial networks during the 2008 financial crisis period and the
result reveals that monoscale model can detect connections within each region while multiscale
model detects centricity and vulnerability in the system by removing the regional effect. On the
other hand, the time-varying model successfully captures the market turbulence during the financial
breakdown. Each of them is helpful to provide certain insight about the financial system. |
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