Physics 555B: Numerical Relativity (Spring 2005)

(Directed studies: 3 Credit Hours)

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Instructors

Bryan Kelleher
Office: Hennings 330A
Office phone: 822-5879
E-mail: kelleher@physics.ubc.ca
Office hours: TBA
Matthew (Matt) W. Choptuik
Office: Hennings 403
Office phone: 822-2412
Home phone: 222-9424
Web: http://laplace.physics.ubc.ca/~matt
E-mail: choptuik@physics.ubc.ca
Office hours: Drop-in (appointment via e-mail phone recommended)
Martin Snajdr
Office: Hennings 408B
Office phone: 822-3860
E-mail: msnajdr@physics.ubc.ca
Office hours: TBA

Course Home Page: http://laplace.physics.ubc.ca/555B/

Prerequisites

Working knowledge of general relativity and associated mathematics, including tensor calculus
Computational physics at the level of PHYS 410

Schedule

TUESDAY & THURSDAY, 1400-1530 -- HENNINGS 302

Links

NEW! EXERCISE PAGE, PLEASE FOLLOW ALONG!! (last update Sun Feb 27, 12 NOON)
NEWS PAGE (last update, Sun, Feb 27, 12 NOON)
ASSIGNED PROJECTS
GROUP PAGES

Recommended Text: General Relativity by R. M. Wald, The University of Chicago Press, 1984.

Course Overview: This course will focus on providing students with an understanding of the formalisms and computational approaches which are currently of most use in studying strong-field aspects of classical general relativity. Lecture topics will include

The Lagrangian formulation of general relativity and other classical field theories (3)
The 3+1 (ADM/Hamiltonian) formulation of GR (5)
The initial-value problem for GR (2)
The evolution problem & coordinate (``gauge'') choices (3)
Spherically symmetric collapse, black hole formation and critical phenomena (7)
Selected topics (5)
Class presentations (1)

(numbers in parentheses indicate roughly how many lectures will be devoted to each topic). Class work will consist primarily of three assigned projects and a term project, all of which will be performed in the context of 2-person teams, whose composition will be determined by students in consultation with the instructor. This work will have a significant computational component, and although computational techniques will be discussed in class from time to time, you may have to ``osmose'' certain skills from the instructor or other members of your team during non-class hours. Computational topics which will be encountered in the course include:

Unix
Fortran 77
Solving ODEs using canned software.
Solving linear systems using canned software.
Solving non-linear equations using Newton's method.
Solving time-dependent PDEs using finite-difference approximations (FDAs)
Solving elliptic PDEs using FDAs and multi-grid techniques
Scientific visualization, primarily using homegrown software such as xvs and DV.

The preferred course language is Fortran 77. Teams are not prohibited from using other languages, but the instructors will not necessarily provide the same level of support for those languages as for Fortran 77. Please follow the hyperlinks for some basic on-line material on the above topics.

Other References: As the course proceeds, a number of additional references will be used, and will be noted here.

Grades

Course grades will be determined on the basis of performance on three assigned group projects and one term group project with the following weighting:

Assigned projects: 50%
Term projects: 50% (40% write-up, 10% oral presentation)

As mentioned above, teams will consist of two students, with composition to be chosen by the students in consultation with the instructors.

Assigned projects

Assigned projects should be treated much like regular homework assignments except that team members must work together to complete the projects. For the most part, the instructor will leave it to the individual teams to ensure that a reasonable balance of work is achieved within each team. Unlike previous courses you may have taken from the instructors, late projects are unlikely to be accepted without an extremely good excuse.

Term projects

On or before 1:30 PM, February 22, each team must present the instructors with a one page summary of their term project, whose topic must have previously been cleared with Choptuik. Choptuik will be happy to suggest term-project topics, but also encourages the teams to pursue, if possible, specific computations of mutual interest. Term-project write-ups will be graded on the basis of a written report (estimated length 20-30 pages including figures and other results), and on an in-class oral presentation (roughly 30 minutes). The written report must be prepared in LaTeX (or TeX) and must be submitted to the Choptuik on or before a date that will be subsequently announced (no exceptions!) The oral presentation per se may be given by any number of group members, although all members should contribute to the preparation of the presentation. Presentation order will be chosen randomly.

Syllabus

Tuesday Thursday

January 11
Lagrangian approach to GR
January 13
Lagangian approach to GR

January 18
Lagrangian approach to GR
January 20
The 3+1 formulation of GR

January 25
The 3+1 formulation of GR
January 27
The 3+1 formulation of GR

February 1
The 3+1 formulation of GR
February 3
The 3+1 formulation of GR

February 8
The initial-value problem for GR
February 10
The initial-value problem for GR

February 15
MIDTERM BREAK
February 17
MIDTERM BREAK

February 22
The evolution problem & coordinate choices
February 24
The evolution problem & coordinate choices

March 1
Spherical symmetry
March 3
Spherical symmetry

March 8
Spherical symmetry
March 10
Spherical symmetry / General relativistic hydrodynamics

March 15
General relativistic hydrodynamics
March 17
General relativistic hydrodynamics

March 22
General relativistic hydrodynamics
March 24
General relativistic hydrodynamics

March 29
General relativistic hydrodynamics
March 31
Selected topics incl. BH critical phen.

April 5
Selected topics incl. BH critical phen.
April 7
Selected topics incl. BH critical phen.

TBA
Group presentations

Tuesday	Thursday
January 11 Lagrangian approach to GR	January 13 Lagangian approach to GR
January 18 Lagrangian approach to GR	January 20 The 3+1 formulation of GR
January 25 The 3+1 formulation of GR	January 27 The 3+1 formulation of GR
February 1 The 3+1 formulation of GR	February 3 The 3+1 formulation of GR
February 8 The initial-value problem for GR	February 10 The initial-value problem for GR
February 15 MIDTERM BREAK	February 17 MIDTERM BREAK
February 22 The evolution problem & coordinate choices	February 24 The evolution problem & coordinate choices
March 1 Spherical symmetry	March 3 Spherical symmetry
March 8 Spherical symmetry	March 10 Spherical symmetry / General relativistic hydrodynamics
March 15 General relativistic hydrodynamics	March 17 General relativistic hydrodynamics
March 22 General relativistic hydrodynamics	March 24 General relativistic hydrodynamics
March 29 General relativistic hydrodynamics	March 31 Selected topics incl. BH critical phen.
April 5 Selected topics incl. BH critical phen.	April 7 Selected topics incl. BH critical phen.
TBA Group presentations

Syllabus Notes

Assigned projects are denoted P1 through P3.
Group project outlines are due FEBRUARY 22 although earlier submissions are encouraged
Term projects due date: TBA

Other Important Dates

Tuesday, January 18: Last day for withdrawal from most Term 2 courses without withdrawal standing of "W" recorded on a student's academic record.
Monday, February 14 to Friday, Feburary 18: Midterm break
Friday, February 15: Last date for withdrawal from most Winter Session Term 2 courses with withdrawal standing of "W" recorded on a student's academic record.

See the UBC 2004/2005 Calendar, Academic Year, PHYS Exam Schedule, Exam Schedule pages for more information