PhD studenship in Math and Stat

---------- Forwarded message
----------From: Alvaro.Faria <aefj2@openmail.open.ac.uk>Date: Wed, Jan
15, 2014 at 2:08 PMSubject: PhD Studentships in Statistics at the Open
UniversityTo: "cpereira@ime.usp.br" <cpereira@ime.usp.br>

Caro Carlinhos,

Feliz 2014!
Espero que esteja tudo bem contigo.

Ficaria grato se puderes divulgar o anuncio abaixo tanto na lista da ABE
quanto ai na USP e em outras listas. Tentei ontem sem sucesso divulgar na lista da ABE.
Acho que tem a ver com o meu email ter sido modificado recentemente.
Divulguei na Allstat e na Bayes-News porem tive que me re-registrar.
Estamos atras de bons alunos que tenham capacidade e interesse de fazer o
Doutorado na Inglaterra num dos projetos descritos.

Grande abraco,

Alvaro

--------------------

We invite applications for two full-time three-year PhD studentships in
Mathematics and Statistics commencing 1st October 2014. PhD students are
based at the University’s Walton Hall campus in Milton Keynes, UK.

Studentships cover full-time fees and include a stipend (currently £13,726
per annum + £1250 per annum to cover training and conference participation).

Overseas applicants are also welcome but those from a non-European Economic
Area country that is not majority English-speaking must hold a Common
European Framework of Reference for Languages (CEFR) certificate for
English at B2 level or higher.

There are currently three PhD projects available in Statistics:

(1) Real time forecasting and monitoring of high frequency data – Álvaro Faria;

(2) Application and comparison of transformations for orthogonality –
Paul Garthwaite; and

(3) Forecasting and monitoring traffic network flows – Catriona Queen.

(Please see below for full details of each project.)

A research proposal is not required, but applicants should make clear which
of the above projects is of interest. Interested persons with a strong
background in Statistics are encouraged to make informal enquiries to
mcs-mathematics-enquiries@open.ac.uk<mailto:mcs-mathematics-enquiries@open.ac.uk>.

General information about studying for a research degree with the Open
University is available from the Research Degrees Prospectus
http://www3.open.ac.uk/study/research-degrees/index.htm and, in particular,
http://www3.open.ac.uk/study/research-degrees/explained/degrees_we_offer/doctor_of_philosophy.htm.

Completed application forms, together with a covering letter indicating
your suitability and reasons for applying, should be sent to:
research-degrees-MCT@open.ac.uk<mailto:research-degrees-MCT@open.ac.uk> to
arrive by 5pm on Friday, 28 February 2014.

Application forms are available from
http://www3.open.ac.uk/study/research-degrees/explained/how_to_apply/mphil_and_phd_application_process.htm

-----------------------------------------------
Statistics PhD projects descriptions:

(1) Real time forecasting and monitoring of high frequency data –
Supervisor: Álvaro Faria

With recent technological advances, there has been an increasing demand
for statistical forecasting models that can detect and quantify patterns,
assess uncertainties, produce forecasts and monitor changes in data from
real-time high-frequency processes in various areas. Those include
short-term electricity load forecasting in energy generation as well as
wireless telemetric biosensing in healthcare where monitoring of patients
in their natural environment is desirable. Usually, many such processes
are well modelled by non-linear auto-regressive (NLAR) models that are
dynamic and can be sequentially applied in real-time. There are a number
of proposed NLAR forecasting models in the literature mostly non-dynamic
and/or not appropriate for real-time applications.

Forecasting and monitoring data from high-frequency processes can be a
multivariate non-linear time series problem. This project takes a Bayesian
approach to the problem, building up on recently proposed analytical
state-space dynamic smooth transition autoregressive (DSTAR) models
that approximate process nonlinearities. DSTAR models have been
shown to be promising for forecasting certain non-linear processes (as
described in the reference listed below), but issues still remain before the
models can be usefully adopted for assimilation of high-frequency data in
practice. This project aims to tackle some of the outstanding issues, such
as the following.

- How to include information from covariates on the DSTAR models without
compromising real-time applicability?
- How to retain model interpretability in relation to STAR model parameters?
- How to effectively model multiple cyclic behaviour of different orders?
- How alternative approximations to nonlinearities improve on the existing
polynomial ones? Would sequential simulation methods such as particle
ﬁltering provide appropriate answers?

Hourly electricity load data for a region in Brazil are available for the
project. The project will involve theoretical developments in statistical
methodology, as well as a large amount of practical work requiring good
statistical programing skills: current software for these models is written in R.

----------------------------------------------------------------------------------------
(2) Application and comparison of transformations for orthogonality –
Supervisor: Paul Garthwaite

In statistics, having variables that are independent or uncorrelated can aid
data analysis and the interpretation of results. Principal component
analysis is the most common method of transforming a set of correlated
x-variables to a set of quantities (the principal components) that are
uncorrelated. A disadvantage of this transformation is that there is no
close association between a principal component and an individual
x-variable – each component typically relates to a number of x-variables
and an x-variable may relate to more than one component.
Two recently proposed transformations are the cos-max transformation
and the cos-square transformation. They each give orthogonal
components and retain the identity of variables: each component is closely
associated with a single x-variable and each x-variable is associated with
a single component. One purpose of this PhD project is to discover and
explore applications of these two transformations, initially focusing on
regression. The transformations have different properties but typically give
similar components. Another purpose of the project is to ﬁnd conditions
under which the properties held by one transformation are approximately
held by the other.

This is a new area of research. To date the transformations have led to the
following new methods (proposed in the references below): (i) a uniﬁed
approach to the identiﬁcation and diagnosis of collinearities,
(ii) a method of setting prior weights for Bayesian model averaging, (iii) a means of
calculating an upper bound for a multivariate Chebyshev inequality, and
(iv) a means of evaluating the contributions of individual variables in a
quadratic form. The diversity of these applications illustrates the scope
of the transformations.

The project will involve theoretical development of statistical methodology
and skills in certain aspects of matrix algebra will be developed. There
will also be a large amount of practical work requiring the use of R.

-------------------------------------------------------------------
(3) Forecasting and monitoring trafﬁc network ﬂows – Supervisor:
Catriona Queen

Congestion on roads is a worldwide problem causing environmental,
health and economic problems. On-line trafﬁc data can be used as part of
a trafﬁc management system to monitor trafﬁc ﬂows at different locations
across a network over time and reduce congestion by taking actions, such
as imposing variable speed limits or diverting trafﬁc onto alternative routes.
Reliable short-term forecasting and monitoring models of trafﬁc ﬂows are
crucial for the success of any trafﬁc management system: this project
will develop such models.

Forecasting and monitoring the trafﬁc ﬂows at different locations across a
network over time, is a multivariate time series problem. This project takes
a Bayesian approach to the problem, using dynamic graphical models.
These models break the multivariate problem into separate, simpler,
subproblems, so that model computation is simpliﬁed, even for very
complex road networks. Dynamic graphical models have been shown to
be promising for short-term forecasting of trafﬁc ﬂows (as described in the
references listed below), but issues still remain before the models can be
used for an on-line trafﬁc management system in practice. This project
aims to tackle some of the outstanding issues, such as the following.

- Any change in trafﬁc ﬂows is often associated with an incident, such as
a road trafﬁc accident. Can a monitor be developed which can detect
any unexpected changes in trafﬁc ﬂow? And can a monitor detect when
a road is reaching capacity, so that congestion is likely to occur?
- When trafﬁc is ﬂowing freely, upstream ﬂows affect ﬂows downstream. In
times of congestion or when there is a road block, queuing vehicles can
cause the relationships between ﬂows at different locations to change so
that downstream ﬂows can affect upstream ﬂows. How can a dynamic
graphical model accommodate these changing relationships over time?
And how can these changes be detected?

Minute-by-minute trafﬁc ﬂow data at a number of different locations at the
intersection of three busy motorways near Manchester, UK, are available
for the project (kindly supplied by the Highways Agency in England:
http://www.highways.gov.uk/). The project will involve theoretical
developments in statistical methodology, as well as a large amount of
practical work requiring good statistical programming skills: current
software for these models is written in R.
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