The immersed boundary method, from 2D fibres to 3D finite elements

The Immersed Boundary Method!
simulating fluid-structure interactions,!
from 2D fibers to 3D finite elements !
Julia E. Samson, Nick A. Battista, Laura A. Miller"
University of North Carolina at Chapel Hill"
December 18th, 2015"

Overview"
1.  The immersed boundary method: when,
who, what, and why?"
2.  The immersed boundary method: how?
(2D)"
3.  Beyond the basics: 3D, IBAMR, and IBFE"
"
Alex Hoover
Tulane University

The IB method: a brief history"
Charles S. Peskin
Courant Institute, NY

Flow patterns around
heart valves: a
digital computer
method for solving
the equations of
motion. PhD thesis,
1972.

The IB method: a brief history"
Laura A. Miller
UNC Chapel Hill
Boyce E. Griffith
UNC Chapel Hill
Charles S. Peskin
Courant Institute

The IB method: deﬁnition"
Viscous
fluid?
Fluid grid
generated from
boundary shape?
IB!!!
J
Not IB
L
Not IB
L

"
"
A numerical method that allows us to simulate
boundaries (objects) in viscous flows, and in
which the fluid grid is not fitted to the boundary
shape."
"

The fluid is modeled on a fixed Cartesian mesh."
"
"
"
"
"
The boundary is modeled on a curvilinear
Lagrangian mesh that moves freely through the
fixed Cartesian mesh."

The IB method: applications"
Alex Hoover
Tulane University
Nick Battista
UNC Chapel Hill
Laura Miller
UNC Chapel Hill

IB: the math below the surface"
1) Fluid"
2) Structure/boundary"
3) Interactions"
We need to know:"
-  how the fluid moves"
-  how the boundary moves"
-  how the boundary impacts the fluid"
-  how the fluid impacts the boundary"

The Navier-Stokes equations"
This is the equation of motion for viscous
ﬂuids."

It basically follows Newton’s Second Law:"
F = m * a"
mass * acceleration
pressure
forces
viscous
forces
other body
forces

Now, we add the equation for
incompressible ﬂow."
mass * acceleration
pressure
forces
viscous
forces
other body
forces
the fluid is incompressible

Fluid mesh"
The fluid is represented
by a fixed (Eulerian)
Cartesian grid."
"
At each point, we solve
for the pressure and
velocity of the fluid
using the Navier-
Stokes equations. The
body forces will be
given by the boundary."

1) Fluid"
3) Interactions"
We need to know:"
-  how the ﬂuid moves ✔"
-  how the boundary moves"

Boundary"
The boundary is represented by a curvilinear Lagrangian
mesh that can move around in the ﬂuid."
"
At each time step, we solve for the position of each
boundary point and for the forces at that point."

1) Fluid"
3) Interactions"
We need to know:"
-  how the boundary moves ✔"

Combining ﬂuid and structure"
+ =
+ interactions!"

Fluid
(fixed Cartesian mesh)
Structure
(moving curvilinear mesh)
moves at local
fluid velocity
exerts
forces on

exerts
forces on
Fluid
Structure
Spread the elastic force density from curvilinear
mesh onto Cartesian grid.

Delta function weights are used to determine how much force is applied
from the elastic boundary to nearby ﬂuid grid cells."

1) Fluid"
3) Interactions"
We need to know:"
-  how the boundary impacts the ﬂuid ✔"

Fluid
Structure
moves at local
fluid velocity
Interpolate the velocity field from the
Cartesian grid onto the curvilinear mesh.

Delta function is used again to determine the velocity at the boundary
point q from ﬂuid velocities near that point."

1) Fluid"
3) Interactions"
We need to know:"
-  how the boundary impacts the ﬂuid ✔"
-  how the ﬂuid impacts the boundary ✔"

We now have a complete formulation for the
immersed boundary method."
" mass * acceleration
pressure
forces
viscous
forces
other body
forces
the fluid is incompressible
Spread the elastic force density from
curvilinear mesh onto Cartesian grid.
Interpolate the velocity
field from the Cartesian
grid onto the
curvilinear mesh.

We now have a complete formulation for the
immersed boundary method."
"

IB time stepping"
At each time step:"
1)  Compute the elastic force
density F on the boundary
mesh."
2)  Spread the elastic force from the
deformed boundary to the
underlying fluid (this is f)."
3)  Solve the equations of fluid
motion defined on the fluid grid
using the elastic body force
density f(x,t) and update the
velocity field."
4)  Move the boundary at the local
fluid velocity. Determine the
velocity at each Lagrangian
point through interpolation."

Making boundaries ﬂexible (or not)"
There are a lot of ﬁber models to control
boundary characteristics like elasticity,
stretchiness, porosity, mass…"
"
3 examples in 2D:"
-  Springs"
-  Torsional springs"
-  Target points"
Nick Battista
UNC Chapel Hill

github.com/nickabattista/IB2d

Nick Battista
UNC Chapel Hill

Springs"
Springs allow longitudinal motion between
two coupled Lagrangian nodes."
ad
RL
RL+d
elastic potential energy
force from
deformation

Springs: the rubber band example"
All Lagrangian
points are
connected by
springs with
resting length 0."
"
Colormap shows
vorticity."
ad

Torsional springs"
Torsional springs allow transversal motion
between three coupled Lagrangian nodes."
ad
θ If θdesired = 180
and C = 0

Torsional springs"
ad
and C = 0
elastic potential energy
curvature

Torsional springs"
ad
and C = 0
deformation forces

Torsional springs: the wobbly beam
example"
All Lagrangian
points are
connected by
beams with
curvature 0."
"
Colormap shows
magnitude of
velocity."
ad

Target points"
Target points are used to prescribe motion of
Lagrangian points or make boundary rigid."
ad

Target points: the pulsing heart
example"
Target point
positions are
updated by
interpolating
between two
positions."
"
Only target points,
no beams or
springs."
"
Colormap shows
pressure."
ad

Pushing the boundary…"
2D IB is where it all started, but newer (and
more complex) methods are available:"
-  3D IB"
-  IBAMR (IB with Adaptive Mesh
Reﬁnement)"
-  IBFE (IB with Finite Elements)"

3D immersed boundary"
Basically the same as 2D but adding a third
dimension."
"
Greatly increases computational cost but
this might be offset by the generation of
more realistic models. "

Collective pulsing in xeniid corals"
Xeniid corals are soft corals that form
pulsing colonies. The pulsing increases local
ﬂow and thus mass transfer."

"
"
This pulsing behavior
seems to be coordinated
and we want to know how
local ﬂow and pulsing
behavior are connected."
Collective
pulsing behavior
Water flow

IB with Adaptive Mesh Reﬁnement"
Boyce E. Griffith
UNC Chapel Hill

Simulating the blood-
muscle-valve mechanics of
the heart by an adaptive
and parallel version of
the immersed boundary
method. PhD thesis, 2005.

Heart valves and blood ﬂow"
Generate 3D simulations
of the interactions
between blood ﬂow and
heart valves to better
understand heart
physiology and to assess
the functioning of
prosthetic valves."
from http://anatomyandphysiologyi.com/heart-anatomy-
chambers-vessels-valves/

A more reﬁned grid will give a better
resolution to the simulation. But it also
greatly increases the computational cost…"
ad
25 x 25 50 x 50 100 x 100 200 x 200

"
So how to have your cake and eat it too???"
ad
25 x 25 50 x 50 100 x 100 200 x 200

Only refine the fluid grid where needed:
close to the boundary and in regions of high
vorticity è Adaptive Mesh Refinement"
ad
25 x 25 50 x 50 100 x 100 200 x 200

ad
Heart development in zebraﬁsh"
4 days post
fertilization"
"
Blood cells and
endocardium are
colored"
"
Two chambers: one
atrium and one
ventricle"
Courtesy of Leigh Ann Samsa and Dr. Jiandong Liu
School of Medicine, UNC Chapel Hill

Ventricle
Atrium
75 um
Courtesy of Leigh Ann Samsa and Dr. Jiandong Liu
School of Medicine, UNC Chapel Hill

ad
Ventricle
Atrium
AV
Canal
Ventricle
IBAMR model

ad
Trabeculae appear to shield the endocardium
from higher shearing forces
velocity field + vorticity map streamlines (after atrium finishes
contraction)

IB with Finite Elements"
A completely different beast…"
ad
Un
Un-1
Un-2
Un+1
Un+2
Un+3
Un-2
Un-1
Un
Un+1
Un+2
Un+3
Un+4
Un+5 Un+6
A collection of
single nodal points
(= fiber)
A collection of
polygonal pieces
(= elements)

IB with Finite Elements"
Generating ﬁnite element meshes is hard
(although there are software packages
available)."
"
But the beneﬁts are enormous:"
-  Simulations run way faster"
-  The FE mesh allows for a more accurate
structure geometry"
-  Material properties are captured way better"
-  Boundaries are less leaky"
-  The models are more stable"

Jellyﬁsh locomotion"
Alexander Hoover
Tulane University

From pacemaker to
vortex ring: modeling
jellyfish propulsion
and turning. PhD
thesis, 2015

Resources"
Code"
2D code examples in MatLab (Nick Battista): github.com/nickabattista/IB2d"
IBAMR code: https://github.com/ibamr/ibamr"
"
Papers"
Griffith, B. E., 2005. Simulating the blood-muscle-valve mechanics of the heart by an adaptive
and parallel version of the immersed boundary method. Ph.D. thesis, New York University."
Mittal, R., Iaccarino, G., 2005. Immersed boundary methods, Annual Review of Fluid Mechanics,
37, 239-261"
Peskin, C. S., McQueen, D. M., 1996. Fluid dynamics of the heart and its valves, In Case Studies
in Mathematical Modeling: Ecology, Physiology, and Cell Biology, Pearson, 313-342"
Peskin, C. S., 2002. The immersed boundary method, Acta Numerica, 11, 1-39"
"
Webpages"
Boyce Griffith: http://griffith.web.unc.edu/ and http://cims.nyu.edu/~griffith/"
Laura Miller: http://miller.web.unc.edu/"
Nick Battista: http://battista.web.unc.edu/"
Alex Hoover: http://hooverap.web.unc.edu/ or email ahoover2@tulane.edu"
"

Acknowledgements"
At UNC"
Laura Miller"
Nick Battista"
Shannon Jones"
Boyce Grifﬁth"
"
"
"
Elsewhere"
Alex Hoover"
Shilpa Khatri"
Uri Shavit"
Roi Holzman"
Funding"
The Company of Biologists"
NSF"

Questions?!
julia@unc.edu"
@juliaesamson"

The immersed boundary method, from 2D fibres to 3D finite elements

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The immersed boundary method, from 2D fibres to 3D finite elements