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Document Description
Title
A
probabilistic
roadmap
based
path
planning
for
visual
servo
of
robotic
manipulators
Author
Arvani
,
Farid.
Description
Thesis
(M.Eng.)--Memorial
University
of
Newfoundland
,
2009.
Engineering
and
Applied
Science
Date
2008
Pagination
xvi, 120 leaves : col. ill.
Subject
Robot
vision;
Robots--Control
systems;
Robots--Motion
Degree
M.Eng.
Degree Grantor
Memorial University of Newfoundland. Faculty of Engineering and Applied Science
Discipline
Engineering and Applied Science
Language
Eng
Notes
Includes
bibliographical
references
(leaves
108-120)
Abstract
Vision
feedback
is
a
competent
control
technique
for a
large
class
of
applications
but they
suffer
from
several
imperfections.
The
well-known
image-based
visual
servo
(IBVS)
methods
regulate
error
in the
image
space
i.e.
the
controller
compares
the
current
view
of the
target
against
the
reference
view
and
generates
an
error
signal
at the
sampling
rate
of the
vision
system.
--
Contrary
to
position-based
visual
servo
(PBVS)
,
which
regulates
error
in
Cartesian
space
,
IBVS
ensures
a
local
stability
and
convergence
in the
presence
of
modeling
error
and
noise
perturbations
since
the
control
loop
is
directly
closed
in the
image
space.
However
,
sometimes
(and
specifically)
when
the
initial
and
desired
configurations
are
distant
, the
camera
trajectory
induced
by
IBVS
is
neither
physically
valid
nor
optimal
due
to the
nonlinearity
and
singularities
in the
relation
from
image
space
to the
workspace
which
can
cause
the
target
to
leave
the
field
of
view.
Furthermore
,
introducing
constraints
such
that the
target
remains
in the
camera
field
of
view
and/or
such
that the
robot
avoids
its
joint
limits
during
servoing
is
not
trivial
in
classical
PBVS
and
IBVS
control
techniques.
When
the
displacement
to
realize
is
large
, this
incapability
leads
to the
failure
of
servoing
process.
--
This
research
presents
a
method
to
resolve
the
problems
associated
with
classical
servo
control.
Visual
servoing
control
solutions
are
local
feedback
control
schemes
and
thus
require
the
definition
of
intermediate
subgoals
at the
task
planning
level.
This
work
introduces
and
details
a
trajectory
planning
scheme
in
order
to
achieve
more
robust
visual
servoing
through
the
introduction
of
subgoal
images.
This
ensures
that the
error
signal
is
kept
small
since
the
current
measurement
always
remains
close
to the
desired
value
so
that
one
can
exploit
the
local
stability
of the
IBVS
control
solution.
The
proposed
method
is
based
on
Probabilistic
Roadmaps
(PRM)
and its
flexible
platform
is
used
to
introduce
desired
constraints
such
as
visibility
constraint
,
joint
limit
constraint
,
obstacle
avoidance
constraint
, and
occlusion
avoidance
constraint
to the
generated
path
at the
task
planning
level.
It
is
noteworthy
that
visibility
constraint
is
intended
to
keep
the
target
in the
camera
field
of
view
(FOV).
Joint
limit
constraint
restricts
the
manipulator
to
avoid
its
joint
limits.
Obstacle
avoidance
and
occlusion
avoidance
constraints
ensure
that the
generated
path
is
collision-
and
occlusion-free.
One
of the
advantages
of the
proposed
method
is
that
targets
are not
required
to have
3D
models.
However
the
method
requires
a
3D
model
of the
obstacles
to
avoid
obstacle
collision
and
occlusion.
--
The
proposed
method
plans
the
camera
trajectory
using
PRM
and then
deduces
the
corresponding
trajectories
in the
image
plane
which
is
a
discrete
geometric
trajectory
of the
target
in the
image
plane.
A
continuous
and
differentiable
cubic
spline
presentation
of the
feature
trajectories
in the
image
plane
is
computed
to be
used
as a
time-varying
reference
to
pure
IBVS
loop.
Off-line
path
planning
is
performed
using
the
kinematics
of a
5-DOF
robot
arm
to
confirm
the
validity
of the
approach.
Simulation
of
different
IBVS
scenarios
is
provided
to
demonstrate
the
performance
of the
proposed
method.
Type
Text
Resource Type
Electronic
thesis
or
dissertation
Format
Image/jpeg;
Application/pdf
Source
Paper copy kept in the Centre for Newfoundland Studies, Memorial University Libraries
Local Identifier
a2953039
Rights
The author retains copyright ownership and moral rights in this thesis. Neither the thesis nor substantial extracts from it may be printed or otherwise reproduced without the author's permission.
Collection
Electronic
Theses
and
Dissertations
Scanning Status
Completed
PDF File
(13.52
MB)
--
http://collections.mun.ca/PDFs/theses/Arvani_Farid.pdf
CONTENTdm file name
32402.cpd
